Molecular Dynamics Simulations and 2H NMR Study of the GalCer/DPPG Lipid Bilayer

doi:10.1529/biophysj.104.054601

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Molecular Dynamics Simulations and ²H NMR Study of the GalCer/DPPG Lipid Bilayer

T. Zaraiskaya and K. R. Jeffrey

Department of Physics, University of Guelph, Guelph, Ontario, Canada

Correspondence: Address reprint requests to K. R. Jeffrey, Dept. of Physics, University of Guelph, Guelph, Ontario, Canada N1G 2W1. Tel.: 519-824-4120; E-mail: krj{at}physics.uoguelph.ca.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSIONS
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Molecular dynamics simulations were performed on a two-componentlipid bilayer system in the liquid crystalline phase at constantpressure and constant temperature. The lipid bilayers were composedof a mixture of neutral galactosylceramide (GalCer) and chargeddipalmitoylphosphatidylglycerol (DPPG) lipid molecules. Twolipid bilayer systems were prepared with GalCer:DPPG ratio 9:1(10%-DPPG system) and 3:1 (25%-DPPG system). The 10%-DPPG systemrepresents a collapsed state lipid bilayer, with a narrow waterspace between the bilayers, and the 25%-DPPG system representsan expanded state with a fluid space of ${approx}$ 10 nm. The number oflipid molecules used in each simulation was 1024, and the lengthof the production run simulation was 10 ns. The simulationswere validated by comparing the results with experimental datafor several important aspects of the bilayer structure and dynamics.Deuterium order parameters obtained from ²H NMR experimentsfor DPPG chains are in a very good agreement with those obtainedfrom molecular dynamics simulations. The surface area per GalCerlipid molecule was estimated to be 0.608 ± 0.011 nm².From the simulated electron density profiles, the bilayer thicknessdefined as the distance between the phosphorus peaks acrossthe bilayer was calculated to be 4.21 nm. Both simulation systemsrevealed a tendency for cooperative bilayer undulations, asexpected in the liquid crystalline phase. The interaction ofwater with the GalCer and DPPG oxygen atoms results in a strongwater ordering in a spherical hydration shell and the formationof hydrogen bonds (H-bonds). Each GalCer lipid molecule makes8.6 ± 0.1 H-bonds with the surrounding water, whereaseach DPPG lipid molecule makes 8.3 ± 0.1 H-bonds. Thenumber of water molecules per GalCer or DPPG in the hydrationshell was estimated to be 10–11 from an analysis of theradial distribution functions. The formation of the intermolecularhydrogen bonds was observed between hydroxyl groups from theopposing GalCer sugar headgroups, giving an energy of adhesionin the range between –1.0 and –3.4 erg/cm². We suggestthat this value is the contribution of the hydrogen-bond componentto the net adhesion energy between GalCer bilayers in the liquidcrystalline phase.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSIONS
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

In biological processes interactions between cells play an importantrole. Understanding the underlying mechanisms of these interactionscan provide information about how cells function and thereforeis a subject of considerable research activity. Much progresshas been achieved in understanding the role of glycosphingolipidsin cell signaling (Ballou et al., 1996; Bektas and Spiegel,2004; Blitterswijk et al., 2003; Boggs et al., 2004; Buciorand Burger, 2004; Hakomori, 2004; Hoekstra et al., 2003) andthe importance of glycosphingolipids in the formation of a compactmyelin structure is well-established experimentally (Bosio etal., 1996; Coetzee et al., 1996; Gourier et al., 2004; Pincetet al., 2001). In recent years, evidence has been accumulatedindicating that the presence of sphingolipids stimulates theformation of lipid domains in plasma membranes (Denny et al.,2004; Hsueh et al., 2002; Simons and Ikonen, 1997; Xu et al.,2001). The roles of these domains have been implicated in signaltransduction across the plasma membrane and in the process ofprotein and lipid sorting, which takes place in intracellularmembranes (Ballou et al., 1996; Degroote et al., 2004; Hoekstraet al., 2003; Simons and Ikonen, 1997). Galactosylceramide (GalCer)belongs to the simplest class of glycosphingolipid since itsheadgroup consists of a single saccharide moiety. GalCer isone of the major components in the lipid bilayer of the myelinmembrane of the central and peripheral nervous systems (Weigandt,1985). Natural and synthetic glycosphingolipids exhibit a complextime-dependent hydration behavior and a high gel to liquid crystallinephase transition temperature in the range of 70–90°C(Haas and Shipley, 1995; Maggio et al., 1985; Moore et al.,1997).

The present work was motivated by the observation of a strongattractive force between uncharged GalCer bilayers across theaqueous solution (Kulkarni et al., 1999) and the ability ofthis system to form a compact (collapsed) state with an extremelynarrow water space between the opposing lipid bilayers. In thatstudy the information about the structure and adhesion energybetween gel-phase GalCer bilayers was obtained by applying x-raydiffraction/osmotic stress techniques. The energy of adhesionbetween GalCer bilayers was estimated to be –1.5 erg/cm².

The strong attractive interactions observed between GalCer lipidbilayers in the gel phase (Kulkarni et al., 1999) should alsooperate between GalCer bilayers in a liquid crystalline phase.Support for this statement comes from a number of publications.Liquid crystalline ditridecanoylphosphatidylcholine bilayerscontaining 30 mol % lactosyl ceramide (LacCer) molecules showa strong adhesion between the bilayers (Yu et al., 1998). Theobserved intermembrane adhesion was explained by the formationof hydrogen bonds between the carbohydrate headgroups. In micropipettestudies the liquid crystalline glycolipids (digalactosyl diacylglycerol) exhibited much stronger adhesion with energies thatwere an order-of-magnitude greater than those found for phosphatidylethanolaminelipids (Evans and Needham, 1987).

On a biological scale, an adhesion energy equal to –1.5erg/cm² is a large value, implying the existence of some attractivemechanism in addition to the van der Waals interaction. It isbelieved that short-range interactions, such as hydrogen bondingbetween carbohydrates, play a major role in the glycolipid adhesionevent (Boggs, 1986; Boggs et al., 2004; Bucior and Burger, 2004;Gourier et al., 2004; Hakomori, 1984, 2004). A similar mechanismwas suggested for hydrated phosphatidylethanolamine lipids (McIntoshand Simon, 1996). This mechanism involves direct hydrogen-bondformation between a group in one bilayer and the in the opposite bilayer. Short-range interactions might also arise because of the polarization ofwater molecules (commonly called a hydration interaction; Randet al., 1988). It has been proposed that both attractive andrepulsive hydration forces contribute to the net interbilayerinteraction (Rand and Parsegian, 1989). The attractive contributionwas defined as the ability of the two opposing lipid headgroupsto form hydrogen-bonded water bridges. The possibility of theindirect hydrogen-bond formation between phosphocholine moleculesvia water molecules has been studied using molecular dynamics(MD) simulations (Pasenkiewicz-Gierula et al., 1997).

Short-range interactions between the lipid bilayers are alwayspresent, but are very difficult to evaluate experimentally.MD simulations can provide unique detailed information aboutthe structure and dynamics of lipid membranes. However, dueto the uncertainties in the force-field parameters, a comparisonof the simulated results with experimental data is essential.Once the results are verified, computer simulations can helpin the interpretation of the experimental data based on thetrajectories of individual atoms.

In this work MD simulations and ²H NMR techniques were usedto investigate the structure and dynamics of the GalCer:DPPGlipid bilayer in water in its liquid crystalline phase. Thegoal of this investigation is to develop experimentally verifiedcomputer models, which can be used in future simulations. Toachieve this goal, we prepared and simulated two systems ofGalCer:DPPG lipid mixtures containing different amounts of water.We used the liquid crystalline phase of the GalCer:DPPG lipidbilayers to compare the order parameter profiles of the dipalmitoylphosphatidylglycerol(DPPG) hydrocarbon chains obtained from MD simulations and ²HNMR experiments. The results of these simulations are also comparedwith the available experimental data: area per lipid, electrondensity profiles, and lipid chain conformations. A number ofimportant structural parameters such as the bilayer thicknessand the thickness of the hydrocarbon chain region, the meannumber of C-D bonds in gauche conformations per lipid chain,and the lipid hydration number were obtained from the simulations.

Natural cerebrosides have a distribution of fatty acid chainlengths varying from 12 to 26 carbons (O'Brien and Rouser, 1964).In the present computer models, the GalCer is represented bythe cerebroside lipid molecule having 18 carbons in the hydroxylatedfatty acid chain. This particular lipid molecule is representativeof natural cerebrosides, since it occurs rather abundantly ( ${approx}$ 20%)in myelin membranes (O'Brien and Rouser, 1964).

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSIONS
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

²H NMR
Sample preparation
Natural bovine brain cerebrosides composed of GalCer and thesodium salt of 1,2-dipalmitoyl-sn-glycero-3-phosphoglyceroldeuterated in carbon positions 1-16 (di-16:0 DPPG d₆₂) on theacyl chains were purchased from Avanti Polar Lipids (Alabaster,AL).

²H NMR measurements were performed on unoriented bilayers composedof GalCer:DPPG lipid mixtures. Initially DPPG and GalCer weredissolved separately in 2:1 chloroform:methanol and then mixed.The solvent was evaporated under a gentle nitrogen gas streamand then under reduced pressure for at least 10 h. The dry lipidmixture was fully hydrated at room temperature in excess (85%by weight) pH7 buffer, which contained 100 mM NaCl and 20 mMHEPES. The sample was frozen rapidly in liquid nitrogen, thenthawed and vortexed at room temperature to get a uniform distributionof lipids throughout the sample. To remove excess water, thesample was centrifuged (4000 rpm, 5 min) at room temperatureand the upper aqueous phase was gently removed. Only the hydratedpellet was used for NMR measurements. Two samples were prepared:a fully hydrated GalCer bilayer containing 10 mol % DPPG, anda fully hydrated GalCer bilayer containing 25 mol % DPPG.

Spectroscopy
The ²H NMR spectra were recorded at a Larmor frequency of 44.667MHz on a homebuilt spectrometer at 80°C, which correspondsto the liquid crystalline phase of the samples. A quadrupoleecho pulse sequence (90°)_y- ${tau}$ _qe-(90°)_x-t-FID (90°pulse of 2.2 µs, ${tau}$ _qe = 50 µs) with phase cyclingwas used to obtain the spectra. A recycle delay of $~$ 10 timesthe spin-lattice relaxation time was applied. After the secondpulse, 2048 data points were collected using quadrature detectionwith a dwell time of 5 µs and a resulting spectral widthof 200 kHz. Fourier transformation starting at the peak of theecho was applied without line broadening.

Deuterium order parameters from NMR experiments
In the case of an axially symmetric lipid motion, the i^th C-Dbond segment yields two symmetric resonance peaks with a quadrupolesplitting of

(1)

In this equation, e²qQ/h is the static quadrupole coupling constant(167 kHz for a C-D bond; Davis, 1983), P₂(cos ${theta}$ ) = 1/2(3 cos² ${theta}$ – 1) is the second rank Legendre polynomial, and ${theta}$ isthe angle between the bilayer normal and the static magneticfield. The value is the C-D bond order parameter defined as (Seelig and Seelig, 1974)

(2)
where ${phi}$ ⁱ = ${phi}$ ⁱ(t) is the angle between the C-D bond vector and the bilayernormal at a time t. The angular brackets indicate a time average.

The measured ²H NMR spectrum is a powder pattern, because allorientations ${theta}$ of the C-D bond vector, with respect to the magneticfield, are allowed. In this so-called Pake-powder spectrum (Davis,1983), the separation between the symmetrical intense horns,denoted as the quadrupolar splitting of the i^th C-D bond, is

(3)

A dePaking procedure (Bloom et al., 1981) can be applied tode-convolve the measured spectrum into subspectra (dePaked spectra)and obtain the order parameters for each C-D bond along thehydrocarbon chain. The dePaking procedure (Klose et al., 1999;Schäfer et al., 1995, 1998; Sternin et al., 2001a,b) thatutilizes the Tikhonov Regularization algorithm (Groetsch, 1984)has been used. The deuterium order parameter profiles S_C–D(n)(n is the position of the C-D bond along the lipid chain) forDPPG hydrocarbon chains were obtained from the dePaked spectra,assuming a monotonic decrease of the S_C–D(n) along thechains following the procedure outlined by Sternin et al. (1988).

MD simulation
Force field
Computer simulations were performed using the 45A3 (Schuleret al., 2001) force field. This force field is a modified versionof GROMOS96 with an improved set of van der Waals parameters,which better reproduces the density and area per lipid in aliquid crystalline bilayer (Chandrasekhar et al., 2003; Schuleret al., 2001). The bonded interactions in the GROMOS96 forcefield are given by

(4)

(5)
wherek_b, k, k, and k are force constants for bonds, angles, dihedrals,and improper dihedrals; n is the dihedral multiplicity; andr₀, ${theta}$ ⁰, ${phi}$ ⁰, and ${xi}$ ⁰ are equilibrium values for the bond lengths,angles, and dihedral and improper dihedral angles. Nonbondedinteractions between atoms i and j are represented as

(6)
where q_i, q_j are the partial charges on atomsi, j; A_ij, and B_ij are the Lennard-Jones parameters; and r_ijis the distance between atoms i and j. The van der Waals parametersbetween different atoms were calculated using the combinationrules A_ij = (A_iiA_jj)² and (Jorgensen et al., 1984).

Molecular topologies for GalCer and DPPG lipid molecules weredeveloped to be compatible with the GROMOS96 force field. Thetopology files for the water molecule and the sodium ion weretaken from the GROMOS96 database. Partial atomic charges forthe GalCer and DPPG lipid molecules were derived based on abinitio quantum mechanical calculations. Firstly, the valuesof the electrostatic potential were calculated at the Hartree-Fockself-consistent field level with the 6-31Gd basis set at thepoints selected according to the Merz-Singh-Kollman scheme usingthe GAUSSIAN98 program. The partial atomic charges were obtainedfrom these calculations by a least-square fitting to the electrostaticpotential. The fitting procedure was performed using the RESPprogram (Bayly et al., 1993). The charges on the hydrogen atomswere added to their carbons in CH, CH₂, and CH₃ groups to formunited atoms. The charge groups (Schuler et al., 2001) wereselected as shown in Fig. 1. The atom types and partial atomiccharges for the GalCer and DPPG lipid molecules used in computersimulations are listed in Tables 1 and 2.

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FIGURE 1 Molecular structures of DPPG and GalCer molecules with the atom names and charge groups used in the simulations. Numbers shown in italics refer to the order parameter calculations.

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TABLE 1 Atom types and charges for the DPPG lipid molecule used in the MD simulations

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TABLE 2 Atom types and charges for the GalCer lipid molecule used in the MD simulations

Simulation conditions
The integration of the equations of motion was performed witha time step of 2 fs using the leapfrog algorithm (Hockney, 1970

).The LINCS algorithm (Hess et al., 1997

) was used to constrainthe length of all bonds. Periodic boundary conditions were appliedalong the three space dimensions to generate an infinite multilamellarsystem. A constant pressure of 1 bar was maintained using theBerendsen coupling method (Berendsen et al., 1984

), scalingall directions separately with a time constant of 1.0 ps. Thearea compressibility was 6.0 x 10^–5 bar^–1 (Lindahland Edholm, 2000b

). A temperature of 80°C was maintainedconstant with the Berendsen coupling method (Berendsen et al.,1984

) using a time constant of 0.1 ps. The gel-to-liquid crystallinephase transition temperature for DPPG is 41°C (Wohlgemuthet al., 1980

) and for GalCer is 70°C (Maggio et al., 1985

),therefore for the simulations the temperature of 80°C waschosen to ensure that the GalCer:DPPG lipid mixture was in aliquid crystalline phase. A twin-range cutoff of 1.0 nm/1.4nm was applied for the van der Waals and Coulomb interactions.The interactions within 1.4 nm were recalculated every sevensteps during the neighbor list update.

To examine the influence of the cutoff on the long-range Coulombinteractions we performed a simulation of the 25%-DPPG systemusing the particle-mesh Ewald method (Darden and Pedersen, 1993).The simulation was carried out for 4 ns starting from the equilibratedstructure. As can be seen in Figs. 2 and 3 during the 4-ns simulationrun, no significant changes were detected in the potential energy,area per lipid, and chain order parameters as compared to thesimulation with a twin-range cutoff. This result disagrees withrecently published investigations (Anezo et al., 2003; Patraet al., 2003). A possible explanation for the difference isthe large size of the present simulation and the relativelyshort time of the particle-mesh Ewald test (4 ns).

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FIGURE 2 The potential energy as a function of time during 10 ns of the production run simulations.

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FIGURE 3 The area per lipid as a function of time during 10 ns of the production run simulations. The average area per lipid is 0.603 ± 0.004 nm² in the 10%-DPPG system and 0.590 ± 0.004 nm² in the 25%-DPPG system.

Deuterium order parameters from MD simulation
Because a united atom model was used for the CH, CH₂, and CH₃groups in these simulations, the positions of the hydrogen atomsrequired for calculations of the C-D order parameters were notavailable directly. The value S_C–D(n) were obtained fromcomputer simulations using the program g_order from the GROMACSpackage, which determines S_C–D(n) from the C_n–C_n–1and C_n–C_n+1 vectors following the procedure defined byEgberts et al. (1994)

Computational details
Computer simulations of the lipid bilayer were carried out usingthe SHARCNET (http://www.sharcnet.ca) high-performance computerfacility located at the University of Guelph Computer Center.Using 20 Compaq Alpha ES40 processors interconnected by a Quadricsnetwork, 17 h/ns were required for the 10%-DPPG system, whereas40 h/ns were required for the 25%-DPPG system. Simulations andanalysis were performed using the GROMACS molecular dynamicspackage, Ver. 3.1.4. (Lindahl et al., 2001). Molecular structureswere examined using the visual molecular dynamics program (http://www.ks.uiuc.edu/research/vmd).

RESULTS AND DISCUSSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSIONS
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Preparation and equilibration of the simulation systems
Initial structure
The initial structure of the lipid bilayer in the liquid crystallinestate was prepared starting with the x-ray crystal structureof the GalCer lipid molecule determined by Pascher and Sundell(1977). Starting from the atomic coordinates of the two GalCercrystal conformers, a 16a x 16b array was prepared by arrangingGalCer molecules according to the symmetry of the crystal structure.The array contained 512 GalCer lipid molecules and representeda single monolayer. This monolayer was then used as the inputfor a short MD simulation run to break the crystal structureof the lipid chains. The temperature of the system was raisedto 510 K for 20 ps (Takaoka et al., 2000), which effectivelyreduced the tilt of the GalCer lipid chains to nearly 0°.During this simulation the positions of the central carbon inthe lipid backbone were fixed. Next, the GalCer-bilayer wasconstructed from two monolayers by rotating one of the monolayersby 180° and then adjusting the interlayer separation sothat there was no overlap of adjacent lipid chains. At thisstep the energy of the system was minimized by using a steepest-descentalgorithm to avoid close contacts between the opposing hydrocarbonchains.

The GalCer-bilayer was then used to prepare a lipid mixtureof GalCer and DPPG lipid molecules. A number of the GalCer lipidmolecules were randomly selected in each monolayer and transformedinto DPPG by changing the atom names in the GalCer moleculeto the atom names in the DPPG molecule; a few extra carbon atomsin the GalCer hydrocarbon chains were removed. Since the DPPGlipid molecule carries a negative charge, an equal number ofsodium ions were added to the system as counterions. To completethe lipid transformation, the energy of the system was minimizedby applying the steepest-descent algorithm. After this procedure,two simulation systems of the GalCer:DPPG lipid mixtures withthe ratios of 9:1 (10%-DPPG system) and 3:1 (25%-DPPG system)were prepared.

The simple point-charge water model (Berendsen et al., 1981)was used to solvate the lipid bilayer. Water molecules wereplaced in the simulation system by using the genbox programfrom the GROMACS package, which fills all free space in thebox including the hydrophobic chain region. The water moleculesappearing in the hydrophobic region were removed from the simulationsystem. It takes up to 20 ns for water molecules to move outinto the water region on their own (Takaoka et al., 2000). Thenumber of water molecules added to the simulation boxes forthe two systems was different. The system containing the GalCer:DPPGlipid mixture with the ratio 9:1 represents the bilayer in acollapsed state with 11 water molecules per lipid (Harvey andSymons, 1978; Kulkarni et al., 1999), and the system with theratio 3:1 represents the bilayer in an expanded state with 49.7water molecules per lipid (Kulkarni et al., 1999).

The final systems were composed of 922 GalCer, 102 DPPG, 102sodium ions, and 11,849 water molecules for a total of 95,000atoms in the 10%-DPPG system, and 768 GalCer, 256 DPPG, 256sodium ions, and 50,963 water molecules for a total of 210,000atoms in the 25%-DPPG system.

Equilibration
The potential energy, surface area per lipid, and volume perlipid were monitored to judge whether the systems had reachedequilibrium. The first two nanoseconds in each simulation werediscarded since this time period was considered the equilibrationperiod for the systems. After the equilibration the trajectorieswere saved every 6 ps and the production run simulation was10 ns in length for each system.

Fig. 2 shows the total potential energy as a function of timeduring the production run simulations. As seen, the total potentialenergy was stable with a standard deviation of <3%. The individualterms of the potential energy function (not shown) were alsostable over the entire course of these simulations.

Fig. 3 shows the surface area per lipid as a function of timeduring the production run simulations. There were some oscillationsof the area per lipid about the average values in both systems.The equilibrated box dimensions were 17.60 x 17.49 x 5.71 nm³for the 10%-DPPG system, and 17.46 x 17.31 x 9.92 nm³ for the25%-DPPG system.

In Fig. 4, snapshots of the simulation systems are presentedat the end of the simulations. In both systems the lipid hydrocarbonchains are disordered, as expected in a liquid crystalline statebilayer. The density of the hydrocarbon chains is lower in themiddle of the bilayer, which is consistent with the fact thatthe methyl groups at the ends of the hydrocarbon chains occupysubstantially more volume per group than the methylene groups(Nagle and Wiener, 1988). Water molecules penetrate deep intothe lipid headgroup region and a few water molecules were foundto go in and out of the hydrophobic bilayer region in the courseof the computer simulation. These observations are in agreementwith experiments (Subezynski et al., 1994; Weaver et al., 1984)and previous MD simulations of phospholipid bilayers in theliquid crystalline phase (Chiu et al., 1995; Marrink and Berendsen,1994; Takaoka et al., 2000; Tu et al., 1995). The sodium ionsexhibit a wide distribution of positions in the water regionin accordance with previous MD simulations of charged lipidbilayers (Cascales et al., 1996a,b; Cascales and de la Torre,1997). Both systems show a tendency for bilayer undulations.This type of collective bilayer movement is a characteristicfeature of lipid bilayer dynamics (Israelachvili and McGuiggan,1988; Israelachvili and Wennerström, 1992; Singer and Nicolson,1972). Bilayer undulations were observed and analyzed by Lindahland Edholm (2000a) in an MD simulation of 1024 DPPC lipid moleculesarranged in a bilayer in its liquid crystalline phase.

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FIGURE 4 Snapshots of the complete systems at the end of the simulations in the 10%-DPPG system (top panel) and the 25%-DPPG system (bottom panel). (Color code: the headgroups of GalCer are white; the headgroups of DPPG are blue; the hydrocarbon chains of GalCer are dark yellow; the hydrocarbon chains of DPPG are lighter yellow; the red spheres are sodium ions; and the water oxygen atoms are gray.)

Static properties
Area per lipid
One of the central parameters in describing the lipid bilayeris the area per lipid, A. The area per lipid shown in Fig. 3was calculated by dividing the area of the simulation box inx,y-plane by the total number of lipids in a monolayer. Thismethod gives a correct value of A only if the simulated lipidbilayer is a one-component system, but for a two-component lipidbilayer this method might lead to significant uncertaintiesfor an individual bilayer component (Petrache et al., 1997

).The area per GalCer lipid molecule was obtained from a separatecomputer simulation of the pure GalCer bilayer. This simulationwas performed at the same temperature and under the same conditionsas the simulations of the GalCer:DPPG lipid mixtures. The simulationsystem was composed of 1024 GalCer lipid molecules and 50,963water molecules. The length of the production run simulationof the pure GalCer bilayer reached 5 ns and the calculated areawas A_GalCer = 0.608 ± 0.011 nm². The starting area perGalCer molecule in the crystal structure was 0.519 nm² (Pascherand Sundell, 1977

). From the simulations of the GalCer:DPPGlipid mixtures the average values of the surface area (A_av)were obtained, which were 0.603 ± 0.004 nm² and 0.590± 0.004 nm² for the 10%-DPPG system and the 25%-DPPGsystem, respectively. Based on these results, the conclusionis that the area per lipid calculated from the pure-GalCer simulationand simulations of the GalCer:DPPG lipid mixtures are the samewithin the error limits. These results also suggest that thearea per DPPG molecule at 80°C does not differ significantlyfrom the area per GalCer molecule. As a point of reference,in a pure DMPG bilayer in its liquid crystalline phase, thearea per lipid headgroup was 0.62 ± 0.02 nm² (Marra,1986

Using x-ray diffraction, Reiss-Husson (1967) determined thesurface area per GalCer molecule in a pure GalCer bilayer tobe 0.67 nm² at 72°C. The value of the area per GalCer lipidobtained from our computer simulation (0.608 ± 0.011nm²) is lower than the above mentioned experimental values (0.67nm²). The experimental method used to determine A_GalCer wasbased on the weighing of the known amounts of water and lipidand determining the bilayer period using x-ray diffraction analysis.There are systematic errors associated with this method thatare difficult to estimate, as can be judged by the range ofvalues quoted for a liquid crystalline DPPC lipid bilayer (0.57nm²–0.709 nm²; Nagle and Wiener, 1988). It has been notedthat this method tends to overestimate the A-value due to thesystematic error introduced by the lipid bilayer undulationsin the liquid crystalline phase (Nagle and Tristram-Nagle, 2000).

Electron density profiles and the bilayer thickness
Electron density profiles were obtained by calculating the electrondensity in 0.05-nm-thick slices perpendicular to the bilayernormal (z-direction of the simulation boxes) and averaged overall frames in the production run trajectory.

The profiles for the 10%-DPPG system are plotted in Fig. 5, a and b,and profiles for the 25%-DPPG system are plotted inFig. 5, c and d. Fig. 5, a and c, shows the profiles for theentire DPPG, water, and sodium ions as well as the contributionsfrom the DPPG headgroup (phosphate P₉), chain methyl groups(carbons C₃₂, C₅₁), and the glycerol ester groups (carbons C₁₆,C₃₅). In both simulation systems the two peaks in the overallDPPG profiles coincide with the glycerol ester carbons (C₁₆,C₃₅). The dip in the middle of the bilayer corresponds to themethyl carbons (C₃₂, C₅₁) located at the end of the DPPG hydrocarbonchains. The region between the dip and the peaks is occupiedby the methylene groups and the region at the outer edges ofeach profile is filled with the bulk water between opposingbilayers. Water molecules were found to surround the headgroupsand to penetrate the hydrocarbon region up to the ester carbons.This observation is consistent with previous experiments (Blumeet al., 1988; Wong and Mantsch, 1988) and simulations (Bergeret al., 1997; Chiu et al.,1995; Marrink et al., 1993; Tu etal., 1995; Zubrzycki et al., 2000). The maximum of the sodiumion distribution is localized near the phosphorus atoms andits density decreases in the bulk water region. The ions werefound to penetrate into the DPPG headgroup region up to thelipid backbone, but not into the lipid hydrocarbon region. Fig.5, b and d, shows the profiles for the whole GalCer lipid moleculeand the contributions of the selected groups: namely the methylgroups (carbons C₂₄, C₄₃), the ester group (carbon C₂₆), thecarbon C₁₀, and the oxygen O₁. The two peaks in the GalCer profilecoincide with the location of the ester carbon C₂₆ and carbonC₁₀, and the valley in the bilayer center corresponds to themethyl carbons (C₂₄, C₄₃) at the end of GalCer chains.

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FIGURE 5 Electron density profiles from the MD simulation for the 10%-DPPG system are shown in a and b, and for the 25%-DPPG system in c and d. The orientation of the water dipole about the bilayer normal ( $<$ cos( ${theta}$ ) $>$ ) with z = 0 corresponds to the location of the bilayer center is shown in e. The electron density profiles are included in a and b for the entire DPPG molecule, the water molecules, the sodium ions, and the following selected atoms: P₉, C₁₆, C₃₅, C₃₂, and C₅₁, and in c and d for the entire GalCer molecule and the following selected atoms: O₁, C₁₀, C₂₆, C₂₄, and C₄₃. The symbol d_h denotes the hydrocarbon chain region, the plus or minus symbols denote the regions with opposite orientations of the water dipole.

From the density profiles in Fig. 5, a and c, the thicknessof the lipid hydrocarbon region, d_h, can be measured as thedistance between the two symmetrical peaks of the C₁₆ or C₃₅profile. The d_h was found to be 3.48 ± 0.05 nm and 3.28± 0.05 nm for the 10%-DPPG and 25%-DPPG systems, respectively.From these values the average chain length was determined tobe $<$ L $>$ = 1.74 nm (half of d_h) for the 10%-DPPG system and 1.64nm for the 25%-DPPG system. To estimate the bilayer thickness,we measured the distance between the two symmetrical peaks correspondingto the positions of the phosphorus atoms (P₉) in the opposingbilayer leaflets. For both simulated systems this distance was4.21 ± 0.05 nm. It is of interest to compare this valuewith the 4.19 ± 0.06 nm, read from the experimental electrondensity profiles for the liquid crystalline DPPC lipid bilayerat room temperature (McIntosh and Simon, 1986

Comparing the overall DPPG and GalCer profiles for the 10%-DPPGand 25%-DPPG systems, one can notice that the dip in the middleof the bilayer is slightly sharper and deeper in the 25%-DPPGsystem (Fig. 5, c and d) than in the 10%-DPPG system (Fig. 5, a and b).At the first glance, this might indicate that thehydrocarbon chains in 10%-DPPG system were more disordered thanin the 25%-DPPG system. However, the thickness of the hydrocarbonregion is smaller in the 25%-DPPG system, which is indicativeof greater disorder in the chain region. A larger percentageof trans-gauche isomerization leads to shorter effective chainlengths in general.

Lipid-water interface: hydrogen-bond formation
The spherically averaged radial distribution functions (RDFvalues) of the oxygen atoms in the water molecules surroundingthe lipid oxygen atoms of the GalCer and DPPG molecules werecalculated using the equation

(7)
whereN(r) is the number of atoms in a spherical shell at distancer and thickness ${delta}$ r from a reference oxygen atom. The value ${rho}$ isthe number of atoms-per-unit volume of the computing box.

The RDF values calculated for the DPPG and GalCer oxygen atomsin 25%-DPPG system were used as a representative data set andare displayed in Fig. 6. The RDF values have the typical shapeseen previously in other lipid bilayer simulations (Cascalesand de la Torre, 1997; Liu and Brady, 1996; Marrink and Berendsen,1994; Pasenkiewicz-Gierula et al., 1997) with peaks and valleysreflecting a non-uniform distribution of water density. Thecharacteristic peaks represent the hydration shells formed bywater molecules around the lipid oxygen atoms. Fig. 6 (top)shows the RDF values calculated for the hydroxyl oxygens (O₂,O₅), ester (O₈, O₁₂) and non-ester (O₁₀, O₁₁) phosphate oxygenson the DPPG headgroup, and for the acyl (O₁₅, O₃₄) and carbonyloxygens (O₁₇, O₃₆) at the beginning of the DPPG hydrocarbonchains. Fig. 6 (bottom) shows the RDF values calculated forthe hydroxyl sugar oxygens (O₂, O₃, O₄, O₆) and the ring sugaroxygen (O₅) on the GalCer headgroup, for the carbonyl (O₈) andhydroxyl oxygens (O₇, O₄₄) at the GalCer fatty acid and sphingosinechains.

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FIGURE 6 Radial distribution functions for the water oxygens around the lipid oxygens of DPPG and GalCer lipid molecules. For the DPPG molecule the RDF values of the following oxygens are shown: hydroxyl oxygens, O₂, O₅; headgroup ester oxygens, O₈, O₁₂; headgroup non-ester oxygens, O₁₀, O₁₁; acyl oxygens, O₁₅, O₃₄; and carbonyl oxygens, O₁₇, O₃₆. For the GalCer molecule the RDF values of the following oxygens are shown: hydroxyl sugar oxygens, O₂, O₃, O₄, O₆; the ring sugar oxygen, O₅; carbonyl oxygen, O₈; hydroxyl oxygens, O₇, O₄₄; and oxygen O₁.

The RDF values for the DPPG oxygen atoms revealed that the orderingof the water molecules is largest (peaks at ${approx}$ 0.27–0.28nm) around the hydroxyl oxygens, non-ester phosphate oxygensin the headgroup region, and around the carbonyl oxygens. Theacyl oxygens of the ester linkage between the fatty acid chainsand the glycerol show no contribution to the hydration. Thisis in agreement with the results obtained from MD simulationsof DMPC (Pasenkiewicz-Gierula et al., 1997

) and DPPC (Marrinkand Berendsen, 1994

) lipid bilayers in water. There is alsoa weak and broad second peak in the RDF of DPPG oxygens O₂,O₅, O₁₀, O₁₁ in the region between 0.4 and 0.6 nm. Second peaksin the RDF of lipid-water pairs were also detected in the previousMD simulation of DPPC in water (Marrink and Berendsen, 1994

)and were interpreted as the second hydration shells of wateraround the lipid headgroups. For GalCer oxygen atoms, the primaryhydration shells are clearly defined for all oxygens, exceptfor the O₅ sugar ring oxygen and O₁ oxygen. The primary hydrationshells of the GalCer hydroxyl oxygens are located between 0.27and 0.28 nm. This is in agreement with the data from the MDsimulation of sugar molecules in aqueous solution by Liu andBrady (1996)

. As in the case of DPPG, a second set of RDF peaksare also observed for some GalCer oxygens. The second peak inthe water density around the sugar hydroxyl oxygens is verybroad and located in the range from 0.4 to 0.6 nm. However,due to the regular ring structure of the sugar unit there isan alternative explanation for the second RDF peak in case ofsugar hydroxyl oxygens (Liu and Brady, 1996

). As the hydroxylgroups in the sugar ring are periodically repeating with a repeatperiod of $~$ 0.3 nm, the RDF of water around hydroxyl groups isexpected to have an oscillatory behavior with the second RDFpeak of any sugar hydroxyl oxygen arising from the primary hydrationshells of its closest neighboring sugar hydroxyl oxygens. Therefore,the strong peak observed in the RDF of oxygen O₅ centered at0.58 nm originates from the primary hydration shells of thehydroxyl oxygens.

The results obtained from the RDF values are consistent withthe fact that the lipids can form H-bonds with water. The numberof H-bonds can be calculated on the basis of the following geometricalcriteria (Pasenkiewicz-Gierula et al., 1997): the distance betweenthe water oxygen and the lipid oxygen must be $≤$ 0.325 nm and theangle between the lipid oxygen, water oxygen, and one of thehydrogen bonds of the water must be $≤$ 35°. Table 3 lists thenumber of hydrogen bonds formed by the individual oxygen atomsin DPPG and GalCer lipid molecules with the surrounding water.Each GalCer molecule makes 8.6 ± 0.1 H-bonds with waterand each DPPG molecule 8.3 ± 0.1 H-bonds. Table 3 comparesthe number of H-bonds between individual DPPG oxygens and waterwith those numbers reported in literature for DMPC (Pasenkiewicz-Gierulaet al., 1997) and DLPE (Berkowitz and Raghavan, 1991). The non-esterphosphate oxygens are involved in most of the hydrogen bonding,whereas the ester phosphate lipid oxygens show only a minorcontribution. The difference in the H-bond numbers for individuallipid oxygens of DPPG and DMPC molecules can be explained bythe high temperature of the present simulation. The total numberof H-bonds for the DPPG molecule (8.3 ± 0.1) is largeas compared to that for the DMPC molecule (4.5 ± 0.2)due to the contribution from the PG-headgroup oxygens (O₂ andO₅), which make, on average, 1.8 + 1.7 = 3.5 extra H-bonds.The formation of the H-bonds between GalCer or DPPG lipid moleculesand water provides strong support for the experimental dataindicating the existence of a significant water-lipid interaction(Boggs, 1986; Lee et al., 1986; Rand et al., 1988; Skarjuneand Oldfield, 1982).

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TABLE 3 The number of H-bonds between the DPPG or GalCer oxygen atoms and the water molecules determined from the present simulation; for comparison, the data for DMPC (Pasenkiewicz-Gierula et al., 1997

) and DLPE (Berkowitz and Raghavan, 1991

) are given

The number of bound water molecules per lipid molecule was obtainedfrom an analysis of the RDF values displayed in Fig. 6 by calculatingthe cumulative number of water molecules within the first hydrationshell. The average number of bounded water molecules was 10–11per DPPG or GalCer molecule. From NMR measurements it was estimatedthat 10–11 waters are required to hydrate the sugar molecule(Harvey and Symons, 1978

), whereas 10–16 waters are requiredto hydrate the phospholipids (Borle and Seelig, 1983

). Our dataare within the range obtained in the above mentioned experiments.

A number of experimental studies (Borle and Seelig, 1983; Randet al., 1988) as well as the theoretical work of Marceljia andRadic (1976) suggest that water molecules are ordered near thelipid headgroups. To demonstrate the effect of water orderingin the present simulations, the orientational profile of thewater dipole along the bilayer normal (z-direction) was calculated.Fig. 5 e plots $<$ cos( ${theta}$ ) $>$ for the water dipole as a function of thez coordinate in 25%-DPPG system. The electron density profilesshow that the hydrocarbon chain region extends from –1.6nm to 1.6 nm. The peaks centered at –2.5 nm and 2.5 nmin the $<$ cos( ${theta}$ ) $>$ plot coincide with the positions of the lipid headgroupsand indicate that ordering of the water dipoles takes placein this region. These water molecules are ordered by the hydrogenbonding with the lipid oxygens. There are two regions with differentsigns of $<$ cos( ${theta}$ ) $>$ , denoted with plus (+) and minus (–) symbols.These regions correspond to the opposite orientations of thewater dipole in the two interfacial regions (Arnold et al.,1983).

Intermolecular H-bonds
The formation of the intermolecular H-bonding between the hydroxylgroups from the opposing GalCer sugar units was observed inthe 10%-DPPG system where there is a narrow water layer betweenthe lipid bilayers. Using the g_hbond program from the GROMACSpackage and the geometrical criteria described above, the numberof sugar-sugar intermolecular H-bonds as a function of timewas calculated. The main contribution to the intermolecularH-bonding was from the opposing GalCer sugar headgroups, whereasother hydroxyl groups as well as the nitrogen atom play minorroles. Based on the results, the average number of the intermolecularH-bonds formed between hydroxyl sugar groups was 15. Assumingthat each H-bond contributes 3–10 kcal/mol (Joesten andSchaad, 1974), the energy of adhesion due to the direct H-bondingbetween opposing GalCer sugar headgroups was estimated to bein the range between –1.0 and –3.4 erg/cm². Consideringthe possibility of the indirect H-bonding via water bridges(Marceljia and Radic, 1976; Rand et al., 1988), it is expectedthat the actual adhesion due to the interbilayer H-bonding iseven greater than this estimate.

It is of interest to compare the simulated and experimentallymeasured adhesion energies. The net adhesion energy betweenGalCer bilayers in the gel phase measured with the x-ray diffraction/osmoticstress techniques was determined to be –1.5 erg/cm² (Kulkarniet al., 1999). For bilayers composed of a mixture of ditridecanoylphosphatidylcholinecontaining 30 mol % LacCer in its liquid crystalline phase,the adhesion force was determined to be –3.5 ±0.5 mN/m (Yu et al., 1998), which corresponds to an adhesionenergy of –0.56 ± 0.08 erg/cm² (Marra and Israelachvili,1985). Unfortunately, experimental data is available only forthe net adhesion energy, which includes contributions from theinterbilayer H-bonding, van der Waals, electrostatic, and otherinteractions. The present simulations do not allow us to determinethe net adhesion energy. However, the H-bond energy obtainedfrom our MD simulations is similar to the experimentally measurednet adhesion between GalCer bilayers or LacCer bilayers, suggestingthat H-bonding is one of the main components of the interactionenergy.

Because of the fast axial reorientation and lateral diffusionof the GalCer molecules in the liquid crystalline phase, theintermolecular H-bonds between the GalCer molecules cannot havea long lifetime. In addition, thermal fluctuations of the bilayerthickness in the liquid phase give rise to steric repulsion(Israelachvili and Wennerström, 1992), which might weakenthe strong attractive contribution due to the H-bond adhesion.To satisfy the dynamic nature of the lipid molecules, the H-bondsbetween two GalCer molecules must be easily broken and thenre-formed with other GalCer molecules. Interestingly, it hasbeen noted that the lifetime of the H-bonds in water shouldbe on the order of 10^–11 s (Boggs, 1986). In the gel phase,where bilayer fluctuations are suppressed and the moleculeshave a more restricted motion, one would expect the intermolecularhydrogen-bond lifetime to be longer. The presence of the H-bondingis thought to be responsible for the high temperature of thegel to the liquid crystalline phase transition. It has beenestimated that one H-bond for every 40 molecules results inan increase in phase transition temperature of $~$ 12°C (Nagle,1976). Natural sphingolipids have a high transition temperaturein the range of 70°C–90°C (Haas and Shipley, 1995;Moore et al., 1997), suggesting that intermolecular hydrogenbonding occurs in the presence of water and stabilizes the gelphase relative to the liquid crystalline phase. At physiologicaltemperature, the myelin membranes are considered to be liquidcrystalline or possibly raftlike liquid-ordered (J. Boggs, personalcommunication). Although no experimental evidence is availableto prove it, one can expect that the myelin membranes wouldbe more ordered than most biological membranes due to the highcontent of sphingolipids and cholesterol. If phase separationof the sphingolipids were to occur, some gel phase domains mightform. The question of the strength and duration of the hydrogenbonds between carbohydrates in the gel and the liquid-crystallinephases could possibly be answered from future MD simulations.

Lipid chain order
Conformational analysis
One measure of the disorder in the lipid bilayer is the meannumber of gauche conformations per lipid hydrocarbon chain,n_g. The conformation is assigned gauche+ (g+) if it has a dihedralangle in the range 120 ± 60°; gauche– (g–)with a dihedral angle in the range –120 ± 60°;and trans with a dihedral angle in the range 0 ± 60°.

For the liquid crystalline DPPC bilayer, n_g is in the rangefrom 3.6 to 4.2 (at 48°C) based on the IR spectroscopy (Mendelsohnet al., 1989) and 3–6 (at 50°C) from ²H NMR measurementsby Seelig and Seelig (1974). The n_g from the present simulationsis 6.17 and 5.85 for the sn1 and sn2 chains of the DPPG molecule,respectively, and 4.44 and 4.76 for the sphingo and fatty acidchains of the GalCer molecule, respectively (see Table 4). Thefact that n_g for the DPPG molecules is close to the high endof the experimental range can be explained by the high temperatureof the present simulation. Table 4 also shows that the percentageof trans conformations in both the DPPG and GalCer moleculesdecreases toward the terminal methyl group of the lipid hydrocarbonchains, as expected from the increasing disorder along the chains.

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TABLE 4 Statistics of the lipid chain conformations from present MD simulations and comparison with experimental data: ²H NMR (Seelig and Seelig, 1974

) and IR (Mendelsohn et al., 1989

) studies

Comparison of the S_C–D obtained from ²H NMR experiments and MD simulations
Experimentally determined deuterium order parameter profilesof the DPPG palmitoyl chains were obtained from the dePakedspectra based on the measured ²H NMR spectra, according to theprocedure described in Materials and Methods.

In Fig. 7 the measured ²H NMR spectra and the correspondingdePaked spectra are shown. The two ²H NMR spectra exhibit characteristicPake-powder patterns with a difference between the maximum valuesof the quadrupole splitting of 27.9 kHz and 25.3 kHz. From thedePaked spectra the order parameters for each carbon along theDPPG palmitoyl chains were assigned.

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FIGURE 7 Experimental ²H NMR and dePaked spectra of fully deuterated palmitoyl chains of DPPG, obtained from the two unoriented samples with different DPPG content. (a) 90 mol % GalCer plus 10 mol % DPPG and (b) 75 mol % GalCer plus 25 mol % DPPG. The tickmarks on the dePaked spectra represent the assigned order parameters as described in the text. The carbons are labeled starting from the lipid backbone.

Fig. 8 compares the simulated and experimental order parameterprofiles S_C–D(n) of the DPPG palmitoyl chains in the 10%-DPPGand the 25%-DPPG systems. The profiles obtained from MD simulationsare the result of averaging over the sn1 and sn2 palmitoyl chainsand over the 10 ns of the production run simulation. The averagingover the two lipid chains was necessary to allow a direct comparisonwith experiments. The simulated and the experimental profilesexhibit similar smooth characteristic patterns. A relativelybroad plateau stretches over the first 5–6 methylene groupsfollowed by a monotonic decrease in the order parameters approachingthe methyl group. The decrease in the profiles is due to thegreater motional freedom of methylene groups toward the endof the hydrocarbon chains. Under our experimental conditions,the quadrupole splittings of the first six methylene groupsof the palmitoyl chains could not be resolved and we cannotunambiguously determine the order parameter values associatedwith these carbons. Therefore, for the first six carbons inthe plateau region, the average values equal to $<$ 0.23 $>$ (the 10%-DPPGsystem) and $<$ 0.22 $>$ (the 25%-DPPG system) were assigned.

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FIGURE 8 Comparison of simulated and experimental deuterium order parameters for palmitoyl chains of DPPG in the 10%-DPPG system (top panel) and the 25%-DPPG system (bottom panel). In the experimental order parameter profiles the marked region represents unresolved values. The error bars are smaller than the size of the plotting symbols.

The agreement between simulation and experiment is very good.Both simulations yield slightly higher-order parameter valuesin the central region, whereas in the end region the agreementis within experimental error (carbons C₁₃, C₁₄ in the 10%-DPPGsystem, carbon C₁₅ in the 25%-DPPG system). The average deviationfrom the experimental values for the 10%-DPPG system and forthe 25%-DPPG system are 0.007, 0.019, i.e., 3.6% and 9.4%, respectively.This result suggests that both simulations are able to reproducethe average structure of the DPPG hydrocarbon chains, especiallywhen the differences in the conformation statistics and timeaveraging between experimental and simulation data are takeninto consideration.

The MD simulations allowed us to perform a more detailed analysisof the order parameters. The order parameter profiles shownin Fig. 9 were calculated for each chain of the DPPG and GalCermolecules. Simulations predict slightly higher-order parametervalues for the GalCer chains than for the DPPG chains in theplateau region. In the plateau region, the order parameter valuesalternate between odd and even carbon numbers. This behavior,known as the odd-even effect, was previously observed in a studyof a phospholipid bilayers (Douliez et al., 1995, 1996). Theresults from our MD simulation show that in the DPPG molecule,only the sn2 chains show the alternating behavior in the plateauregion, whereas the sn1 chain demonstrates a smooth profile.This observation supports the idea that the two hydrocarbonchains of the phospholipid are not equivalent. The differencebetween the two lipid chains became evident when ²H NMR experimentswere performed on selectively deuterated hydrocarbon lipid chains(Seelig and Seelig, 1974). The use of two perdeuterated lipidchains does not allow the observation of the difference betweenthe two chains. A comparison of the order parameter profilesobtained for DPPG palmitoyl chains in the 10%-DPPG and the 25%-DPPGsystems (Fig. 9) suggests that the lipid-chain order/disorderhas little connection with the collapsed-expanded system transition.

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FIGURE 9 Simulated deuterium order profiles for DPPG hydrocarbon chains (top panel) and for GalCer hydrocarbon chains (bottom panel).

It should be noted that ²H NMR measurements were performed usingnatural cerebrosides. Naturally occurring cerebrosides are oftenhighly asymmetric with a distribution of the fatty acid chainlength ranging from 12 to 26 carbons (O'Brien and Rouser, 1964

).The predominant ${alpha}$ -hydroxylated fatty acid is 18 or 24 carbonslong without any double bond (C18h:0 and C24h:0). The nonhydroxylatedfatty acid contains mostly 24 carbons with one unsaturated carbonbond (C24:1). The sphingosine chain is only 18 carbons longand penetrates into the bilayer to a depth of 13 or 14 carbons(Dahlen and Pascher, 1979

). This accumulation of the long fattychain cerebrosides in natural membranes has important consequences.The chain asymmetry may lead to the formation of regions interdigitatingacross the bilayer or to the protrusion of the carbohydrateheadgroup above the membrane surface and also to a partial exposureof the acyl chain region. The latter may result in an increasedinteraction between the bilayers across the water region andpossibly greater intermolecular hydrogen bonding could occur.The effect of hydroxylation of the long fatty acid chain mayalso promote the adhesion by its participation in hydrogen bonding.In the present computer model the cerebrosides are representedby GalCer lipid molecules having a C18h:0 fatty acid chain.The chains of the GalCer lipid may not be sufficiently asymmetricin the chain length to observe the effect of chain interdigitation.Therefore, in the future it would be of interest to create acomputer model with GalCer molecules having a distribution oflong fatty chain lengths to reproduce a natural asymmetry ofthe chains. Such a simulation would help to resolve the questionabout the chain interdigitation and/or the possible differencein the number of hydrogen bonds across the water region.

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSIONS
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Force-field topologies have been developed for the GalCer andDPPG molecules that are compatible with the GROMOS96 force field.Using this force field, two large bilayer systems of GalCer:DPPGlipid mixtures in the compact (collapsed) and expanded stateshave been simulated. This is the first MD simulation of thelipid mixture composed of glyco- (GalCer) and phospho- (DPPG)lipids. Both simulations were successful and yield results thatagree with experimental observables, such as the deuterium orderparameters of the lipid chains, the surface area per lipid,the bilayer thickness, and the thickness of the chain region.It would be of interest to further compare the electron densityprofiles obtained from our MD simulations with those from detaileddiffraction experiments.

The interaction of water with the GalCer and DPPG oxygen atomsresulted in a strong water ordering via a spherical hydrationshell and the formation of H-bonds. The computer simulationssuggest that each GalCer lipid molecule makes 8.6 ± 0.1H-bonds with water and each DPPG lipid molecule 8.3 ±0.1. From the RDF values the number of water molecules requiredto hydrate the lipid was calculated to be 10–11 per GalCeror DPPG lipid molecule. The formation of H-bonds provides strongsupport for the experimentally observed lipid-water interactions.

New information was obtained in this study regarding the originof the large adhesion energy between GalCer bilayers. We foundthat the main difference between the collapsed and expandedstate bilayers was the formation of the direct H-bonds betweenhydroxyl groups from the opposing GalCer lipid molecules inthe collapsed state. By calculating the number of H-bonds betweenopposing bilayers in the collapsed state system, the energyof adhesion due to sugar-sugar H-bonding was estimated to bein the range between –1.0 and –3.4 erg/cm². We suggestthat this value is the contribution of the H-bond componentof the net adhesion energy between GalCer bilayers in the liquidcrystalline phase.

A detailed investigation of the dynamics of GalCer:DPPG lipidbilayer on a longer timescale is currently in progress.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSIONS
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

The major part of our MD simulations was performed using theSHARCNET facilities located at the University of Guelph computercenter.

Submitted on October 14, 2004; accepted for publication February 28, 2005.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSIONS
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

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