In this paper, we describe a relatively simple lattice model of a two-component, two-state phospholipid bilayer. Application of Monte Carlo methods to this model permits simulation of the observed excess heat capacity versus temperature curves of dimyristoylphosphatidylcholine (DMPC)/distearoylphosphatidylcholine (DSPC) mixtures as well as the lateral distributions of the components and properties related to these distributions. The analysis of the bilayer energy distribution functions reveals that the gel-fluid transition is a continuous transition for DMPC, DSPC, and all DMPC/DSPC mixtures. A comparison of the thermodynamic properties of DMPC/DSPC mixtures with the configurational properties shows that the temperatures characteristics of the configurational properties correlate well with the maxima in the excess heat capacity curves rather than with the onset and completion temperatures of the gel-fluid transition. In the gel-fluid coexistence region, we also found excellent agreement between the threshold temperatures at different system compositions detected in fluorescence recovery after photobleaching experiments and the temperatures at which the percolation probability of the gel clusters is 0.36. At every composition, the calculated mole fraction of gel state molecules at the fluorescence recovery after photobleaching threshold is 0.34 and, at the percolation threshold of gel clusters, it is 0.24. The percolation threshold mole fraction of gel or fluid lipid depends on the packing geometry of the molecules and the interchain interactions. However, it is independent of temperature, system composition, and state of the percolating cluster.
Nystatin isolated from Streptomyces is a polyene antibiotic that is frequently used in the treatment and prophylaxis of fungal infections. Here, the fractional sterol concentration dependencies of the partition coefficient for partitioning of nystatin into ergosterol/dimyristoyl-L-alpha-phosphatidylcholine (DMPC), cholesterol/DMPC, ergosterol/1-palmitoyl-2-oleoyl-L-alpha-phosphatidylcholine (POPC), and ergosterol/POPC/1-palmitoyl-2-oleoyl-L-alpha-phosphatidylethano lam ine (POPE) multilamellar vesicles have been determined fluorometrically at 37 degrees C using approximately 0.3-1.0 mol % sterol concentration increments over a wide concentration range (e.g., 18-54 mol % sterol). This unconventional approach of varying membrane sterol content, in contrast to previous studies using large sterol concentration increments (e.g., 10 mol %), leads to a striking observation. The partition coefficient of nystatin changes dramatically with membrane sterol content in a well-defined alternating manner, displaying a local minimum at or very close to the critical sterol mole fractions (e.g., 20.0, 22.2, 25.0, 33.3, 40.0, and 50.0 mol % sterol) predicted for sterols regularly distributed in either hexagonal or centered rectangular superlattices. In ergosterol/DMPC bilayers, for example, there is a >3-fold increase in nystatin partitioning with a minute change (approximately 1 mol %) in sterol content on either side of the critical sterol mole fraction, 25.0 mol %. These results provide semifunctional evidence supporting the sterol regular distribution model [Chong, P. L.-G. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 10069-10073]. More importantly, these results reveal a new membrane phenomenon, that is, that nystatin partitioning is affected by the extent of sterol regular distribution in the plane of the membrane. This phenomenon occurs not only in saturated (e.g., DMPC) but also in unsaturated (e.g., POPC) lipid membranes, and persists in the presence of polar headgroup heterogeneity (e.g., POPC/POPE). This membrane property points to a new method for studying the interactions of polyene antibiotics with sterol-containing membranes, and the need to consider the membrane sterol content of the target cells when administering nystatin or other polyene antibiotics.
We have examined the fractional sterol concentration dependence of dehydroergosterol (DHE) fluorescence in DHE/cholesterol/dimyristoyl-L-alpha-phosphatidylcholine (DMPC), DHE/ergosterol/DMPC and DHE/cholesterol/dipalmitoyl-L-alpha-phosphatidylcholine (DPPC) liquid-crystalline bilayers. Fluorescence intensity and lifetime exhibit local minima (dips) whenever the total sterol mole fraction, irrespective of the DHE content, is near the critical mole fractions predicted for sterols being regularly distributed in hexagonal superlattices. This result provides evidence that all three of these naturally occurring sterols (e.g., cholesterol, ergosterol, and DHE) can be regularly distributed in the membrane and that the bulky tetracyclic ring of the sterols is the cause of regular distribution. Moreover, at the critical sterol mole fractions, the steady-state anisotropy of DHE fluorescence and the calculated rotational relaxation times exhibit distinct peaks, suggesting that membrane free volume reaches a local minimum at critical sterol mole fractions. This, combined with the well-known sterol condensing effect on lipid acyl chains, provides a new understanding of how variations in membrane sterol content change membrane free volume. In addition to the fluorescence dips/peaks corresponding to hexagonal superlattices, we have observed intermediate fluorescence dips/peaks at concentrations predicted by the centered rectangular superlattice model. However, the 22.2 mol% dip for centered rectangular superlattices in DHE/ergosterol/DMPC mixtures becomes diminished after long incubation (4 weeks), whereas on the same time frame the 22.2 mol% dip in DHE/cholesterol/DMPC mixtures remains discernible, suggesting that although all three of these sterols can be regularly distributed, subtle differences in sterol structure cause changes in lateral sterol organization in the membrane.
A global optimization method for intensity-restrained structure refinement, based on variable target function (VTF) analysis, is illustrated using experimental data on a model peptide, gramicidin-S (GS) dissolved in DMSO. The method (referred to as VARTIGO for variable target intensity-restrained global optimization) involves minimization of a target function in which the range of NOE contacts is gradually increased in successive cycles of optimization in dihedral angle space. Several different starting conformations (including all-trans) have been tested to establish the validity of the method. Not all optimizations were successful, but these were readily identifiable from their large NOE R-factors. We also show that it is possible to simultaneously optimize the rotational correlation time along with the dihedral angles. The structural features of GS thus obtained from the successful optimizations are in excellent agreement with the available experimental data. A comparison is made with structures generated from an intensity-restrained single target function (STF) analysis. The results on GS suggest that VARTIGO refinement is capable of yielding better quality structures. Our work also underscores the need for a simultaneous analysis of different NOE R-factors in judging the quality of optimized structures. The NOESY data on GS in DMSO appear to provide evidence for the presence of two orientations for the ornithine side chain, in fast exchange. The NOESY spectra for this case were analyzed using a relaxation rate matrix which is a weighted average of the relaxation rate matrices for the individual conformations.
Here, the interplay between membrane cholesterol lateral organization and the activity of membrane surface-acting enzymes was addressed using soil bacteria cholesterol oxidase (COD) as a model. Specifically, the effect of the membrane cholesterol mole fraction on the initial rate of cholesterol oxidation catalyzed by COD was investigated at 37 degrees C using cholesterol/1-palmitoyl-2-oleoyl-l-alpha-phosphatidylcholine (POPC) large unilamellar vesicles (LUVs, approximately 800 nm in diameter). In the three concentration ranges examined (18.8-21.2, 23.6-26.3, and 32.2-34.5 mol % cholesterol), the initial activity of COD changed with cholesterol mole fraction in a biphasic manner, exhibiting a local maximum at 19.7, 25.0, and 33.4 mol %. Within the experimental errors, these mole fractions agree with the critical cholesterol mole fractions (C(r)) (20.0, 25.0, and 33.3) theoretically predicted for maximal superlattice formation. The activity variation with cholesterol content was correlated well with the area of regular distribution (A(reg)) in the plane of the membrane as determined by nystatin fluorescence. A similar biphasic change in COD activity was detected at the critical sterol mole fraction 20 mol % in dehydroergosterol (DHE)/POPC LUVs (approximately 168 nm in diameter). These results indicate that the activity of COD is regulated by the extent of sterol superlattice for both sterols (DHE and cholesterol) and for a wide range of vesicle sizes (approximately 168-800 nm). The present work on COD and the previous study on phospholipase A(2) (sPLA(2)) [Liu and Chong (1999) Biochemistry 38, 3867-3873] suggest that the activities of some surface-acting enzymes may be regulated by the extent of sterol superlattice in the membrane in a substrate-dependent manner. When the substrate is a sterol, as it is with COD, the enzyme activity reaches a local maximum at C(r). When phospholipid is the substrate, the minimum activity is at C(r), as is the case with sPLA(2). Both phenomena are in accordance with the sterol superlattice model and manifest the functional importance of membrane cholesterol content.
Glycolipid transfer proteins (GLTPs) are small, soluble proteins that selectively accelerate the intermembrane transfer of glycolipids. The GLTP fold is conformationally unique among lipid binding/transfer proteins and serves as the prototype and founding member of the new GLTP superfamily. In the present study, changes in human GLTP tryptophan fluorescence, induced by membrane vesicles containing glycolipid, are shown to reflect glycolipid binding when vesicle concentrations are low. Characterization of the glycolipid-induced "signature response," i.e. ϳ40% decrease in Trp intensity and ϳ12-nm blue shift in emission wavelength maximum, involved various modes of glycolipid presentation, i.e. microinjection/dilution of lipidethanol solutions or phosphatidylcholine vesicles, prepared by sonication or extrusion and containing embedded glycolipids. High resolution x-ray structures of apo-and holo-GLTP indicate that major conformational alterations are not responsible for the glycolipid-induced GLTP signature response. Instead, glycolipid binding alters the local environment of Trp-96, which accounts for ϳ70% of total emission intensity of three Trp residues in GLTP and provides a stacking platform that aids formation of a hydrogen bond network with the ceramide-linked sugar of the glycolipid headgroup. The changes in Trp signal were used to quantitatively assess human GLTP binding affinity for various lipids including glycolipids containing different sugar headgroups and homogenous acyl chains. The presence of the glycolipid acyl chain and at least one sugar were essential for achieving a low-tosubmicromolar dissociation constant that was only slightly altered by increased sugar headgroup complexity. Glycolipid transfer protein (GLTP)4 is a soluble (ϳ24-kDa) protein that selectively transfers glycosphingolipids (GSLs) between membranes. GSLs play key roles in cell recognition, adhesion, differentiation, proliferation, and programmed death in normal and disease states (1-8). Phylogenetic/evolutionary analyses show GLTP to be highly conserved among vertebrates (9 -11). The conformational uniqueness of the GLTP fold when compared with other lipid binding/transfer proteins (12-14) has resulted in GLTP being designated the prototype and founding member of the GLTP superfamily (15, 16). GLTP employs a novel two-layer "sandwich motif," dominated by ␣-helices and achieved without intramolecular disulfide bridges, to accommodate glycolipid within a single lipid binding site and to form a membrane-interaction domain that differs from other known membrane targeting/translocation domains, i.e. C1, C2, PH, PX, and FYVE (9, 13, 17-21). The glycolipid binding site of GLTP consists of a sugar headgroup recognition center that anchors the ceramide-linked sugar to the protein surface via multiple hydrogen bonds and a hydrophobic tunnel that accommodates the hydrocarbon chains of ceramide. The crystal structures of glycolipid-free GLTP and of GLTP complexed with a half-dozen glycolipids differing in sugar headgroup and/or lipid acyl c...
The lateral distribution of 1-palmitoyl-2-[10-(1-pyrenyl)decanoyl]phosphatidylcholine (PyrPC) was studied in small unilamellar vesicles of 1,2-dipalmitoyl-, 1,2-dimyristoyl-, and 1-palmitoyl-2-oleoyl-phosphatidylcholine (DPPC, DMPC, and POPC, respectively) under anaerobic conditions. The DPPC and DMPC experiments were carried out over temperature ranges above and below the matrix phospholipid phase transition temperature (Tm). The excimer to monomer fluorescence intensity ratio (E/M) was determined as a function of temperature for the three PyrPC/lipid mixtures. Phase and modulation data were used to determine the temperature dependence of pyrene fluorescence rate parameters in gel and in liquid-crystalline bilayers. These parameters were then used to provide information about excited-state fluorescence in phospholipid bilayers, calculate the concentration of the probe within liquid-crystalline and gel domains in the phase transition region of PyrPC in DPPC, and simulate E/M vs. temperature curves for three systems whose phase diagrams are different. From the simulated curves we could determine the relationship between the shape of the three simulated E/M vs. temperature curves and the lateral distribution of the probe. This information was then used to interpret the three experimentally derived E/M vs. temperature curves. Our results indicate that PyrPC is randomly distributed in pure gel and fluid phosphatidylcholine bilayers.(ABSTRACT TRUNCATED AT 250 WORDS)
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