Oleic and Docosahexaenoic Acid Differentially Phase Separate from Lipid Raft Molecules: A Comparative NMR, DSC, AFM, and Detergent Extraction Study

doi:10.1529/biophysj.104.044552

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Oleic and Docosahexaenoic Acid Differentially Phase Separate from Lipid Raft Molecules: A Comparative NMR, DSC, AFM, and Detergent Extraction Study

Saame Raza Shaikh^*, Alfred C. Dumaual^*, Alicia Castillo, Daniel LoCascio^*, Rafat A. Siddiqui, William Stillwell^* and Stephen R. Wassall^¶

^* Department of Biology, Indiana University-Purdue University, Indianapolis, Indiana; Medical Biophysics Program, Indiana University School of Medicine, Indianapolis, Indiana; Cellular Biochemistry Laboratory, Methodist Research Institute at Clarian Health, Indianapolis, Indiana; and ^¶ Department of Physics, Indiana University-Purdue University, Indianapolis, Indiana

Correspondence: Address reprint requests to William Stillwell, Dept. of Biology, Indiana University-Purdue University, 723 W. Michigan St., Indianapolis, IN 46202-5132. Tel.: 317-274-0580; Fax: 317-274-2846; E-mail: wstillwe{at}iupui.edu.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

We have previously suggested that the ${omega}$ -3 polyunsaturated fattyacid, docosahexaenoic acid (DHA) may in part function by enhancingmembrane lipid phase separation into lipid rafts. Here we furthertested for differences in the molecular interactions of an oleic(OA) versus DHA-containing phospholipid with sphingomyelin (SM)and cholesterol (CHOL) utilizing ²H NMR spectroscopy, differentialscanning calorimetry, atomic force microscopy, and detergentextractions in model bilayer membranes. ²H NMR and DSC (differentialscanning calorimetry) established the phase behavior of theOA-containing 1-[²H₃₁]palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine(16:0-18:1PE-d₃₁)/SM (1:1) and the DHA-containing 1-[²H₃₁]palmitoyl-2-docosahexaenoyl-sn-glycero-3-phosphoethanolamine(16:0-22:6PE-d₃₁)/SM (1:1) in the absence and presence of equimolarCHOL. CHOL was observed to affect the OA-containing phosphatidylethanolamine(PE) more than the DHA-containing PE, as exemplified by >2xgreater increase in order measured for the perdeuterated palmiticchain in 16:0-18:1PE-d₃₁/SM (1:1) compared to 16:0-22:6PE-d₃₁/SM(1:1) bilayers in the liquid crystalline phase. Atomic forcemicroscopy (AFM) experiments showed less lateral phase separationbetween 16:0-18:1PE-rich and SM/CHOL-rich raft domains in 16:0-18:1PE/SM/CHOL(1:1:1) bilayers than was observed when 16:0-22:6PE replaced16:0-18:1PE. Differences in the molecular interaction of 16:0-18:1PEand 16:0-22:6PE with SM/CHOL were also found using biochemicaldetergent extractions. In the presence of equimolar SM/CHOL,16:0-18:1PE showed decreased solubilization in comparison to16:0-22:6PE, indicating greater phase separation with the DHA-PE.Detergent experiments were also conducted with cardiomyocytesfed radiolabeled OA or DHA. Although both OA and DHA were foundto be largely detergent solubilized, the amount of OA that wasfound to be associated with raft-rich detergent-resistant membranesexceeded DHA by almost a factor of 2. We conclude that the OA-PEphase separates from rafts far less than DHA-PE, which may haveimplications for cellular signaling.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

It is well recognized that dietary intake of ${omega}$ -3 polyunsaturatedfatty acids (PUFAs) has profound benefits on normal health andprevention of chronic disease states, although the molecularmechanism responsible remains unclear. One possibility is that ${omega}$ -3 PUFAs are incorporated into the plasma membrane, influencingmembrane structure and function (Jump, 2002; Stillwell, 2000).Of special importance for human health is docosahexaenoic acid(DHA), the longest and most unsaturated fatty acid commonlyfound in the plasma membrane. With 22 carbons and 6 cis doublebonds located at positions 4, 7, 10, 13, 16, and 19, DHA's uniquemolecular structure (Eldho et al., 2003) renders it a primarycandidate for affecting properties of the membrane. It has beenproposed by us (Brzustowicz et al., 2002a; Shaikh et al., 2002)and others (Huster et al., 1998; Mitchell and Litman, 1998)that DHA may be specifically involved in inducing lateral phaseseparations into DHA-rich/cholesterol-poor and DHA-poor/cholesterol-richlipid microdomains. A reduced affinity between the DHA acylchain and cholesterol has been hypothesized to promote phaseseparations, perhaps affecting lipid rafts (Stillwell and Wassall,2003).

Lipid rafts are postulated to be specialized liquid-ordered(l_o) lipid microdomains rich in sphingolipids and cholesterol.They are involved in serving as platforms for cellular signalingevents (Ahmed et al., 1997; Edidin, 1993, 2003a; Hooper, 1999)by accumulating specific proteins, including GPI-anchored proteinsand the src-family of kinases. In addition, rafts are thoughtto influence lipid trafficking events, pathogen entry, and cytoskeletalorganization (Munro, 2003). The supposed stability of lipidrafts is attributed to the favorable interaction between theamide of the sphingosine backbone and the hydroxyl of an adjacentsphingolipid as well as hydrogen bonding between the 3-OH ofcholesterol and the sphingosine amide. Saturated acyl chainsare thought to promote formation of rafts since they are moreextended than unsaturated chains and pack well amongst themselvesand with cholesterol. Consequently, phospholipids containinghighly disordered polyunsaturated acyl chains that exhibit lowaffinity to cholesterol would be expected to phase separatefrom the rafts.

We suggested in a preliminary investigation that an oleic acid(OA)-containing phosphatidylethanolamine (PE) and a DHA-containingPE may phase separate differently from the lipid raft moleculessphingomyelin (SM) and cholesterol (CHOL) in monolayer and bilayermembranes (Shaikh et al., 2002). Here we elucidate the effectthat replacing the OA-containing 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine(16:0-18:1PE) with the DHA-containing 1-palmitoyl-2-docosahexaenoyl-sn-glycero-3-phosphoethanolamine(16:0-22:6PE) has on phase separation from SM and CHOL. PE waschosen as our model phospholipid since it is the second mostabundant polar lipid found in mammalian plasma membranes andit is often in PE that DHA accumulates (Simopoulos et al., 1986;Zerouga et al., 1996). Partial lipid asymmetry is a characteristicof all membranes. Approximately one-sixth of plasma membranePE is found in the outer leaflet where it would interact withthe abundant SM (approximately five-sixths of the total SM).In the inner leaflet, the abundant PE (approximately five-sixthsof the total PE) would interact with the less abundant SM (approximatelyone-sixth of the total SM). Therefore, in both membrane leafletsthere are sufficient quantities of both PE and SM to affectmembrane structure (Simons and Vaz, 2004). PEs normally existas heteroacid sn-1 saturated, sn-2 unsaturated species. We employ16:0-18:1PE as our "typical" phospholipid because oleic acidis the most abundant unsaturated fatty acid in membranes and16:0-22:6PE constitutes our "modified" phospholipid.

In this study we explore differences in lateral phase separationbetween 16:0-18:1PE/SM/CHOL (1:1:1) and 16:0-22:6PE/SM/CHOL(1:1:1) bilayers employing solid state ²H NMR spectroscopy,differential scanning calorimetry (DSC), atomic force microscopy(AFM), and detergent extraction. ²H NMR and DSC are first usedto characterize the phase behavior of our model membrane systemsin the absence and presence of cholesterol. Subsequent analysisof ²H NMR spectra in the lamellar liquid crystalline phase,AFM measurements, and detergent-resistant experiments in modelmembranes demonstrate marked differences in the molecular interactionsof 16:0-18:1PE versus 16:0-22:6PE with raft molecules. We alsoextend our studies to include detergent-resistant studies withliving cardiomyocytes. These studies are discussed in relationto the physiological importance of rafts.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

Materials
Egg SM, 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine(16:0-18:1PE), 1-[²H₃₁]palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine(16:0-18:1PE-d₃₁), 1-palmitoyl-2-docosahexaenoyl-sn-glycero-3-phosphoethanolamine(16:0-22:6PE), and 1-[²H₃₁]palmitoyl-2-docosahexaenoyl-sn-glycero-3-phosphoethanolamine(16:0-22:6PE-d₃₁) were purchased from Avanti Polar Lipids (Alabaster,AL). CHOL was obtained from Sigma Chemical Co. (St. Louis, MO).Lipid purity was assessed with thin layer chromatography. Lipidand cholesterol concentrations were quantified using phosphateand gravimetric analyses, respectively. Deuterium-depleted H₂Oused in the ²H NMR studies was obtained from Isotec (Miamisburg,OH). High-performance thin layer chromatography (HPTLC) plateswere purchased from Alltech (Deerfield, IL). All organic solventswere HPLC grade and obtained from Fisher Scientific (Pittsburgh,PA). Molecular Probes (Eugene, OR) was the source of choleratoxin subunit B, horseradish peroxidase conjugate. The radiolabeledfatty acids [¹⁴C]DHA and [³H]OA were obtained from PerkinElmer(Boston, MA) The cardiomyocyte isolation kit was purchased fromWorthington Biochemical (Lakewood, NJ). Horse and fetal bovineserums were from Hyclone (Logan, UT).

²H NMR sample preparation
²H NMR samples were prepared taking stringent precautions toprevent oxidation, as described before (Shaikh et al., 2002).Lipid mixtures containing 100 mg total lipid were codissolvedin chloroform, dried under argon gas, and placed under vacuumovernight. After vacuum pumping, the mixtures were hydratedto 50 wt % with 50 mM Tris buffer (pH 7.4) and vigorously vortexedfor $~$ 5 min. The pH was corrected in the presence of 2 mL additionaldeuterium-depleted H₂O, and the samples were then frozen andlyophilized multiple times at $~$ 50 mTorr to reduce the ²H NMRsignal from residual ²HHO. After hydrating the powders to 50wt %, the resultant aqueous multilamellar dispersions were transferredto 5-mm glass NMR tubes and stored at –20°C when notin use. All samples were allowed to equilibrate to room temperaturefor $~$ 1 h before experimentation. As previously reported (Brzustowiczet al., 2002b; Shaikh et al., 2002), we have compared phospholipid/cholesterolsamples prepared as described here and by the low-temperaturetrapping method (Huang et al., 1999) designed to ensure thatlipids do not demix during removal of the solvent. Both methodsyielded essentially identical results.

²H NMR spectroscopy
Solid-state ²H NMR spectra were acquired on a home-built spectrometeroperating at a resonance frequency of 27.6 MHz. A double resonanceprobe (Cryomagnet Systems, Indianapolis, IN) with a 5-mm transverse-mountedcoil was utilized. Temperature was controlled (±0.5°C)with a Love Controls (1600 series) temperature controller (MichiganCity, IN). Spectral parameters were as stated previously (McCabeet al., 1994; Shaikh et al., 2003a).

Analysis of ²H NMR spectra
Moments were calculated from ²H NMR spectrafor 16:0-18:1PE-d₃₁ or 16:0-22:6PE-d₃₁ in PE/SM (1:1) and PE/SM/CHOL(1:1:1) mixtures with

(1)
where ${omega}$ is thefrequency with respect to the central Larmor frequency ${omega}$ ₀, f( ${omega}$ )is the lineshape, and n is the order of the spectral moment(Davis, 1983). In practice the integral is a summation overthe digitized data. The expression

(2)
relatesthe first moment M₁ to the average order parameter of the perdeuterated palmitic sn-1 chain via the static quadrupolarcoupling constant (e²qQ/h) = 167 kHz in the lamellar liquidcrystalline phase.

Spectra were also fast Fourier transform (FFT) depaked to enhanceresolution in the lamellar liquid crystalline phase (McCabeand Wassall, 1997). The depaking procedure numerically deconvolutesthe powder pattern signal to a spectrum representative of aplanar membrane of single alignment. The depaked spectra consistof doublets with quadrupolar splittings that equate to order parameters by

(3)
where is the angle the membrane normal makes with the magnetic field and is the second-order Legendre polynomial. Smoothed profiles of order along the perdeuteratedpalmitoyl sn-1 chain were then constructed on the basis of integratedintensity assuming monotonic variation toward the disorderedcenter of the bilayer (Lafleur et al., 1989).

Differential scanning calorimetry
DSC experiments were conducted as previously described (Shaikhet al., 2001). Briefly, lipid mixtures, codissolved in chloroform,were dried under argon gas followed by $~$ 12 h under vacuum toensure the removal of residual organic solvent. Samples containingDHA were prepared under dark conditions in a glovebox with anargon atmosphere to control for oxidation. Multilamellar vesicles(MLVs) were made by hydrating the appropriate phospholipidsat 5 mg/ml in 10 mM sodium phosphate buffer (pH 7.4) with subsequentremoval of oxygen. MLV solutions were frozen in dry ice andthawed three times in a water bath above the gel-to-liquid crystallinephase transition temperature (T_m) of the lipids. The MLV solutions(500 µL) were added to each of the three chambers of aCalorimetry Sciences differential scanning calorimeter (AmericanFork, Utah) whereas the fourth chamber contained 500 µLof the buffer. Heating and cooling scans were made at 0.125°C/min.Only the cooling scans are presented although data derived fromboth scans appeared nearly identical. Deconvolution of the multicomponent16:0-18:1PE/SM (1:1) scan was accomplished with Microcal OriginSoftware (Northampton, MA).

AFM sample preparation
Lipid mixtures codissolved in chloroform were dried under argongas and placed in a vacuum overnight. Two mL of buffer solution(10 mM MOPS, 200 mM NaCl, 0.1 µM EGTA, pH 7.4) warmedabove the phase transition was added to the dried lipid filmat a final concentration of 1 mM to make MLVs as described above.Large unilamellar vesicles (LUVs) of 0.1 µm diameter wereformed by initially extruding the MLV suspension multiple timesthrough a 1.0-µm pore-sized nucleopore polycarbonate filter(Whatman, Clifton, NJ) and subsequently through a 0.1-µmnucleopore filter using a miniextruder (Avanti Polar Lipids).Fifty-nm diameter small unilamellar vesicle (SUV) lipid suspensionswere made by additionally passing the LUV suspension througha 0.05-µm nucleopore filter. Lipid preparation and AFMexperiments were conducted in the dark and under degassed, argongas-saturated conditions to prevent oxidation.

Supported bilayers
Supported bilayer formation using LUV suspensions was adaptedfrom Tokumasu et al (2003). Briefly, 20 µL of the LUVsuspension was placed on a freshly cleaved mica surface, incubatedfor 30–60 s, and then washed with buffer. Excess solutionwas removed and fresh degassed buffer solution was added tothe sample and allowed to incubate for 30–60 min beforeimaging. Alternatively, supported bilayers were also formedusing an SUV suspension (Rinia et al., 2002). In this case,75 µL of the SUV suspension with a lipid concentrationof $~$ 0.5 mM was added to the freshly cleaved mica surface. Lipidvesicles were allowed to absorb to the mica surface for a periodof 10 h at 4°C. Afterwards, the sample was rinsed with buffersolution and warmed above the phase transition temperature for60 min and then allowed to cool to room temperature. Sampleswere rinsed once more and fresh, degassed buffer solution wasadded before imaging. Images from LUV and SUV vesicle depositionshowed nearly identical results.

Atomic force microscopy
Supported bilayer samples were placed in a liquid cell holderattached to a Bioscope AFM (Digital Instruments, Santa Barbara,CA) set on a vibration-free air table. Bilayer surfaces wereimaged using the tapping mode at a scanning rate of 0.5–1.0Hz and a tapping frequency of $~$ 7.8 kHz using DNP-S20 oxide-sharpenedtips with a spring constant of 0.06 N/m (Digital Instruments).All images were scanned over a 10 x 10-µm area at roomtemperature (23°C). Images were acquired from four separateexperiments for each lipid composition with a minimum of fourimages (from separate areas of the bilayer) per experiment foranalysis. Image analysis was conducted with software providedby Digital Instruments in addition to NIH Image J software.

Detergent-resistant studies
Detergent-resistant studies were conducted as described by others(Gandhavadi et al., 2002; Schroeder et al., 1994). Lipid mixtures(2 mg) of either 16:0-18:1PE/SM/CHOL (1:1:1) or 16:0-22:6PE/SM/CHOL(1:1:1) were codissolved in chloroform and dried under a gentlestream of argon gas. Samples were then placed in a vacuum fora minimum of $~$ 6 h to remove trace amounts of organic solvent.MLVs were prepared by adding 1 mL of phosphate-buffered saline(PBS) (Cambrex, East Rutherford, NJ) into the samples and hydratingthem for 30 min at 45°C with intermittent vortexing. MLVswere then incubated at 4 or 40°C for 30 min in the presenceof 1% Triton X-100 and subsequently centrifuged at the appropriatetemperature in a Beckman (Fullerton, CA) table-top centrifuge(TL100) for 1 h at 200,000 g. Supernatants detergent solublemembranes (DSMs) and pellets detergent resistant membranes (DRMs)were separated and washed for 90 min with SM-2 Adsorbent Bio-Beads(Bio-Rad, Hercules, CA) to remove Triton X-100 (Gandhavadi etal., 2002). DSMs and DRMs were lyophilized for $~$ 10 h to removeH₂0 and then dissolved in chloroform and subjected to HPTLCanalysis.

HPTLC analysis
SM, CHOL, and PE lipids were separated as described (Grahamand Higgins, 1997) on HPTLC plates. Plates were developed (halfwayup the plate) twice in chloroform-methanol-water (60:30:5 byvolume) followed by a third development (to the top of the plate)with hexane-diethyl ether-acetic acid (80:20:1.5 by volume).They were then charred ( $~$ 190°C) in 5% CuSO₄/4% H₃PO₄ solutionfor 10 min and analyzed using a Kodak Image Station.

Isolation of cardiomyocytes and cell culture
Neonatal cardiomyocytes were isolated using a cell isolationsystem from Worthington Biochemical (Lakewood, NJ). Hearts wereisolated from 1- to 3-day-old Wistar rats. Connective tissueand atria were removed from the hearts and ventricles were subsequentlyminced into $~$ 1-mm blocks and digested with trypsin overnight.Trypsin activity was neutralized the following day and tissueswere further digested with collagenase. Single-cell isolationwas achieved by filtering the cell suspension through a 70-µmfilter. Cells were then preplated to remove fibroblasts andcardiomyocytes were isolated using the isolation protocol accompanyingthe kit (Worthington). Dead cells and cellular debris were removedby centrifugation on a 5-mL Opti-Prep density gradient solution(Axis-Shiel PoC, As, Oslo, Norway). Isolated neonatal cardiomyocyteswere cultured for 24 h in a humidified incubation chamber inthe presence of 95% O₂/5% CO₂ on laminin- and collagen-coatedplates in F-10 media (containing 10% horse serum, 5% fetal bovineserum, 100 units/mL penicillin, 100 µg/mL streptomyocin,and 0.1 mM bromodeoxyuridine).

Incorporation of radiolabeled fatty acids
Cardiomyocytes were washed with serum-free media twice and thentreated with 5 µM DHA or OA in the presence of trace amountsof [¹⁴C]DHA (0.2 µCi/mL) and [³H]OA (1 µCi/mL),respectively, under serum-free conditions for 24 h. Free fattyacid solutions containing radiolabeled fatty acids were preparedfreshly each time from stock solutions by dissolving the compoundsin EtOH with a final EtOH concentration in warmed culture medium $≤$ 0.05%. The concentration of free fatty acids used was basedon cell viability measurements using WST-1 (Roche Biochemicals,Indianapolis, IN).

Isolation of detergent-resistant membranes
Cells were scraped and dissolved in 1 mL of cold Mes-bufferedsaline (MBS; 150 mM NaCl, 25 mM Mes, pH 6.5) in the presenceof 1% (w/v) Triton X-100. Cells were incubated for 30 min at4°C and then homogenized on ice. Cold MBS (1.5 mL) was addedto the homogenate and 2 mL of this suspension was mixed with2 mL of 90% (w/v) sucrose in MBS. The mixture was then addedonto a sucrose gradient consisting of 8 mL of 5–35% (w/v)sucrose in MBS. All solutions were supplemented with a proteaseinhibitor cocktail (Roche Biochemicals). Sucrose gradients werethen subjected to centrifugation in a Beckman SW40 (Fullerton,CA) swinging bucket rotor at 200,000 g for 20 h at 4°C.Fractions of 1 mL each were collected from the top to the bottomof the tubes, vortexed, and stored at –80°C untilfurther use. Fifty µL of each isolated sucrose gradientfraction containing [³H]OA or [¹⁴C]DHA was placed in a scintillationvial, mixed with scintillation fluid, and counted using a Beckmanscintillation counter (LS 6000 IC).

ß-cholera toxin binding to GM1
Dot blots were obtained to test for localization of GM1, a raftmarker (Brown and London, 2000), in sucrose gradient fractionsof cardiomyocytes. Twenty µL of each fraction was loadedonto a nitrocellulose paper and placed under a vacuum for 2h. The nitrocellulose was then blocked in Blocker Blotto (Pierce,Rockford, IL) for 1 h and then incubated in peroxidase labeledß-cholera toxin overnight (1:1000) in TTBS (50 mMTris-HCl, 150 mM NaCl, 0.05% Tween-20, pH 7.4) in the cold.Blots were then washed three times in TTBS buffer and developedusing an enhanced-chemiluminescence kit and x-ray film. X-rayfilms were quantified using a Kodak Image Station.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

Characterization of phase behavior for 16:0-18:1PE-d₃₁/SM (1:1) versus 16:0-22:6PE-d₃₁/SM (1:1) in the absence and presence of equimolar CHOL
Fig. 1 presents ²H NMR spectra for aqueous multilamellar dispersionsof 16:0-18:1PE-d₃₁/SM (1:1) and 16:0-22:6PE-d₃₁/SM (1:1) at5, 25, and 40°C. The approach is to use the perdeuteratedsn-1 chain as an intrinsic probe of molecular organization forthe phospholipid in the manner advocated by, for example, Petracheet al. (2001) who examined DHA-containing phosphatidylcholines(PCs) with a series of saturated sn-1 chains. Both 16:0-18:1PE-d₃₁/SM(1:1) (Fig. 1 a) and 16:0-22:6PE-d₃₁/SM (1:1) (Fig. 1 d) at5°C show featureless broad spectra characteristic of thegel phase with shoulders at ±63 kHz. The spectral shapeis rendered nonaxially symmetric (asymmetry parameter ) by slow rotational diffusion of the all trans 16:0acyl chains (Wassall et al., 1986). Increasing the temperatureto 25°C results in a narrowing of the spectra to ±19kHz for 16:0-18:1PE-d₃₁/SM (1:1) (Fig. 1 b) and ±16 kHzfor 16:0-22:6PE-d₃₁/SM (Fig. 1 e), indicating fast axial rotationassociated with the onset of lamellar liquid crystalline phase.Spectra recorded at 40°C for 16:0-18:1PE-d₃₁/SM (1:1) (Fig.1 c) and 16:0-22:6PE-d₃₁/SM (1:1) (Fig. 1 f) are characterizedby spectral edges at ±15 kHz, and are representativeof the lamellar liquid crystalline phase in which there is rapidisomerization about the carbon-carbon bonds.

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FIGURE 1 ²H NMR spectra for 50 wt % aqueous dispersions in 50 mM Tris buffer (pH 7.4) of 16:0-18:1PE-d₃₁/SM (1:1) and 16:0-22:6PE-d₃₁/SM (1:1). Spectra for 16:0-18:1PE-d₃₁/SM (1:1) were recorded at (a) 5, (b) 25, and (c) 40°C. Spectra for 16:0-22:6PE-d₃₁/SM (1:1) were also recorded at (d) 5, (e) 25, and (f) 40°C.

Fig. 2 illustrates the effect of equimolar CHOL on the phasebehavior of 16:0-18:1PE-d₃₁/SM (1:1) and 16:0-22:6PE-d₃₁/SM(1:1) bilayers at 5, 25, and 40°C. All samples at 5, 25,and 40°C produce powder patterns characteristic of the liquidcrystalline state. Although spectral peaks at 5°C are poorlyresolved for 16:0-18:1PE-d₃₁/SM/CHOL (1:1:1) (Fig. 2 a) and16:0-22:6PE-d₃₁/SM/CHOL (1:1:1) (Fig. 2 d), particularly inthe former system, the PE component in either lipid mixturedisplays spectral edges at ±28 kHz, indicative of fastaxial rotation. Upon increasing the temperature to 25 or 40°Cenhanced spectral resolution becomes apparent and a differentialreduction in width is observed between 16:0-18:1PE-d₃₁/SM/CHOL(1:1:1) (Fig. 2, b and c) and 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1)(Fig. 2, e and f). The sharp edges of the spectrum for 16:0-18:1PE-d₃₁/SM/CHOL(1:1:1) bilayers occur at ±25 kHz (25°C) and ±23kHz (40°C) in comparison to ±22 kHz (25°C) and±19 kHz (40°C) for 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1).A greater increase in order due to the sterol for the OA-containingcomponent than the DHA-containing component in the mixtureswith SM is indicated.

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FIGURE 2 ²H NMR spectra for 50 wt % aqueous dispersions in 50 mM Tris buffer (pH 7.4) of 16:0-18:1PE-d₃₁/SM/CHOL (1:1:1) and 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1). Spectra for 16:0-18:1PE-d₃₁/SM/CHOL (1:1:1) were recorded at (a) 5, (b) 25, and (c) 40°C. Spectra for 16:0-22:6PE-d₃₁/SM/CHOL were also recorded at (d) 5, (e) 25, and (f) 40°C.

Figs. 1 and 2 only present examples of spectra at selected temperatures.However, spectra for 16:0-18:1PE-d₃₁/SM (1:1), 16:0-18:1PE-d₃₁/SM/CHOL(1:1:1), 16:0-22:6PE-d₃₁/SM (1:1), and 16:0-22:6PE-d₃₁/SM/CHOL(1:1:1) were acquired over a wide temperature range from –10to 40°C. To illustrate the effect of temperature on phasebehavior, Fig. 3, a and b, presents the first moment M₁ as afunction of temperature for all four of the lipid mixtures.For 16:0-18:1PE-d₃₁/SM (1:1) bilayers (Fig. 3 a), adoption ofgel phase by 16:0-18:1PE-d₃₁ is signified by M₁ > 10 x 10⁴s^–1 for temperatures <20°C. The liquid crystallinestate, characterized by M₁ < 6.5 x 10⁴ s^–1, was adoptedat temperatures >25°C. The sharp drop in M₁ value thataccompanies the gel-to-liquid crystalline phase transition iscentered at $~$ 23°C (represented by X in Fig. 3 a). There isno longer a discontinuity in the temperature variation of thefirst moment after the addition of equimolar CHOL to 16:0-18:1PE-d₃₁/SM(1:1) (Fig. 3 a). The values gradually decrease (10.5–8.0x 10⁴ s^–1) over the temperature range plotted, indicatinga broadening of the phase transition to near obliteration.

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FIGURE 3 (a and b) Variation in the first moment M₁ (Eq. 1) as a function of temperature for bilayers of (a) 16:0-18:1PE-d₃₁/SM (1:1) and 16:0-18:1PE-d₃₁/SM/CHOL (1:1:1), and (b) 16:0-22:6PE-d₃₁/SM (1:1) and 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1). M₁ is plotted logarithmically and values have a ±2% error. The transition temperature T_m, designated by X, is the midpoint of the sharp drop in moment that accompanies the chain-melting transition. (c and d) Corresponding DSC cooling scans for (c) 16:0-18:1PE/SM (1:1) and 16:0-18:1PE/SM/CHOL (1:1:1), and (d) 16:0-22:6PE/SM (1:1) and 16:0-22:6PE/SM/CHOL (1:1:1). The scans with cholesterol are slightly offset along the excess heat capacity axis to aid observation. The inset is a high-resolution deconvolution of the DSC cooling scan for 16:0-18:1PE/SM (1:1). The dotted and dashed lines represent the 16:0-18:1PE-rich and SM-rich phases, respectively.

For 16:0-22:6PE-d₃₁/SM (1:1) (Fig. 3 b) bilayers, M₁ > 10x 10⁴ s^–1 characterized the lamellar gel phase correspondingto temperatures <5°C. The lamellar liquid crystallinephase exists at temperatures >10°C, where M₁ < 7 x10⁴ s^–1. The abrupt change in M₁ that accompanies thechain melting transition of 16:0-22:6PE-d₃₁ in the mixed membraneoccurs at $~$ 7°C (represented by X in Fig. 3 b). The momentsfor 16:0-22:6PE-d₃₁/SM (1:1) also demonstrate that SM servesto stabilize the bilayer. They signify the lamellar phase throughoutthe temperature range studied, whereas we detected a transitionto the inverted hexagonal phase at T_h = 13°C for 16:0-22:6PE-d₃₁with ²H NMR spectroscopy (Shaikh et al., 2003a

). The momentsfor 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1) continuously decrease (10.5–5.7x 10⁴ s^–1) from –10 to 40°C (Fig. 3 b). As with16:0-18:1PE-d₃₁/SM/CHOL (1:1:1), a lack of sharp discontinuityin the M₁ values indicates that the chain-melting transitionfor the labeled PE component within the mixed membrane has beenbroadened beyond detection by the introduction of sterol. Onthe basis of spectral moments measured for 16:0-22:6PE-d₃₁,we previously found that a gel-to-liquid crystalline transitionremained when equimolar cholesterol was added to the polyunsaturatedmembrane (Shaikh et al., 2003a

). The implication is that bothsphingomyelin and sterol contribute to the broadening of thetransition for 16:0-22:6PE-d₃₁ in 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1).

Fig. 3 also presents DSC cooling scans, for comparative purposes,for 16:0-18:1PE/SM (1:1) (Fig. 3 c) and 16:0-22:6PE/SM (1:1)(Fig. 3 d) bilayers in the absence and presence of equimolarCHOL. The cooling scan for 16:0-18:1PE/SM (1:1) (Fig. 3 c) displaysa broad exotherm, which was deconvoluted into two transitions(Fig. 3, inset) that we ascribe to 16:0-18:1PE-rich/SM-poor(T_m = 26.1°C) and 16:0-18:1PE-poor/SM-rich (T_m = 30.1°C)transitions. The clear observation of two separate exothermsat other PE/SM ratios provided a rationale for deconvolutionwith the 1:1 mixture (Shaikh et al., unpublished data). 16:0-22:6PE/SM(1:1) (Fig. 3 d) shows two distinct exotherms with T_m = 8 and24°C. We attribute them, respectively, to transitions for16:0-22:6PE-rich/SM-poor and 16:0-22:6PE-poor/SM-rich phases.The T_m value for the 16:0-22:6PE-rich/SM-poor phase coincideswith the temperature of the transition identified on the basisof spectral moments for 16:0-22:6PE-d₃₁/SM (1:1) (Fig. 3 b).Addition of equimolar CHOL to 16:0-18:1PE/SM (1:1) and 16:0-22:6PE/SM(1:1) eliminates all of the transitions seen in the absenceof the sterol by DSC.

Equimolar CHOL increases the order of 16:0-18:1PE-d₃₁ in 16:0-18:1PE-d₃₁/SM (1:1) more than 16:0-22:6PE-d₃₁ in 16:0-22:6PE-d₃₁/SM (1:1) bilayers
The differential effect of adding equimolar CHOL on 16:0-18:1PE-d₃₁/SM(1:1) versus 16:0-22:6PE-d₃₁/SM (1:1) bilayers in the liquidcrystalline phase is clear upon examination of the plot of M₁values against temperature in Fig. 3 (a and b). We specificallycompared the ordering effect of CHOL on 16:0-18:1PE-d₃₁/SM (1:1)versus 16:0-22:6PE-d₃₁/SM (1:1) at 40°C. Table 1 summarizesthe first moment M₁ and the average order parameter calculated from M₁ via Eq. 2 for all four of thelipid combinations at 40°C. Addition of equimolar CHOL to16:0-18:1PE-d₃₁/SM (1:1) results in an increase in for 16:0-18:1PE-d₃₁ by 61%, whereas the change in for 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1) comparedto 16:0-22:6PE-d₃₁/SM (1:1) bilayers is $~$ 26%. Although thesevalues represent a population-weighted average over all coexistingenvironments between which the deuterated PE molecules exchange,greater interaction of the sterol with the OA- than the DHA-containingPE may be unambiguously inferred.

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TABLE 1 Data derived from ²H NMR studies of 16:0-18:1PE-d₃₁/SM (1:1) or 16:0-22:6PE-d₃₁/SM (1:1) in the absence or presence of equimolar CHOL at 40°C

The ²H NMR spectra at 40°C (Figs. 1 and 2) were FFT depakedto enhance spectral resolution (McCabe and Wassall, 1997

). Applicationof the algorithm produces a spectrum that is equivalent to thespectrum that would be obtained for a planar membrane with thebilayer normal parallel to the magnetic field (Fig. 4). Theypossess an outermost composite doublet, representing orderedmethylenes in the upper part of the acyl chain, and five tosix well-resolved doublets corresponding to the methylenes andterminal methyl that display progressively less order in thelower portion of the sn-1 acyl chain. The depaked data wereutilized to calculate profiles of order parameter S_CD alongthe perdeuterated sn-1 chain of the PE component in the lipidmixtures (Fig. 5). The smoothed profiles were created by assigningequal integrated intensity to each methylene group and a monotonicdecrease in order toward the terminal methyl was assumed (Lafleuret al., 1989

). Fig. 5 illustrates order parameters as a functionof acyl chain carbon position for bilayers of 16:0-18:1PE-d₃₁/SM(1:1) (Fig. 5 a) and 16:0-22:6PE-d₃₁/SM (1:1) (Fig. 5 b) inthe absence or presence of equimolar CHOL at 40°C. A similarqualitative trend is observed for all four of the order parameterprofiles. The upper part of the perdeuterated palmitoyl chainsis marked by a plateau region of approximately constant orderwith a subsequent decrease in order toward the bottom of thechains. In agreement with the average order parameters

listed in Table 1, addition of CHOL to both phospholipidmixtures results in ordering of the acyl chains at all carbonpositions. CHOL's ordering effect is most pronounced in theplateau region toward the top of the perdeuterated acyl chainfor both 16:0-18:1PE-d₃₁ and 16:0-22:6PE-d₃₁ as opposed to themiddle of the bilayers. At carbon position 2, for instance,the value of S_CD changes from $~$ 0.24 to $~$ 0.37 for 16:0-18:1PE-d₃₁/SM(1:1), and for 16:0-22:6PE-d₃₁/SM (1:1) shows a smaller change $~$ 0.24 to $~$ 0.32. The respective differences in S_CD correspond toa sterol-induced increase of 54.2 and 33.3%. This differentialin the effect of CHOL on the OA- and DHA-containing mixturesis consistent with the calculated changes in

reported in Table 1.

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FIGURE 4 FFT depaked spectra for (a) 16:0-18:1PE-d₃₁/SM (1:1); (b) 16:0-18:1PE-d₃₁/SM/CHOL (1:1:1); (c) 16:0-22:6PE-d₃₁/SM (1:1); and (d) 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1) at 40°C.

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FIGURE 5 Smoothed order parameter profiles generated from depaked spectra at 40°C for bilayers of (a) 16:0-18:1PE-d₃₁/SM (1:1) and 16:0-18:1PE-d₃₁/SM/CHOL (1:1:1), and (b) 16:0-22:6PE-d₃₁/SM (1:1) and 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1).

AFM measurements demonstrate differences in phase separation between 16:0-18:1PE/SM/CHOL (1:1:1) vs. 16:0-22:6PE/SM/CHOL (1:1:1)
AFM is a useful tool for assessing phase separations in supportedbilayers. The AFM measurements reported here are a preliminaryattempt to relate the differences in phase separation seen spectroscopicallyby NMR with lateral organization. Fig. 6 presents AFM imagesof 16:0-18:1PE/SM/CHOL (1:1:1) and 16:0-22:6PE/SM/CHOL (1:1:1)supported bilayers on mica obtained at room temperature in thelamellar liquid crystalline phase. Visual inspection clearlyreveals differences in the topology of the two lipid mixtures.For both samples, the thicker (lighter) patches are assignedto SM-rich or SM/CHOL-rich domains whereas the thinner (darker)regions are assigned to PE-rich phases. The former regions extendabove the latter on average by 1.1 ± 0.1 nm (Fig. 6,insets). The SM-rich or SM/CHOL-rich domains were identifiedbased upon varying the amount of SM or SM/CHOL in our lipidmixtures (data not shown). In the case of 16:0-18:1PE/SM/CHOL,the lighter domains comprise 26 ± 2% of the total bilayersurface (Fig. 6, top) whereas 59 ± 10% of the total bilayersurface was covered by lighter domains in the 16:0-22:6PE/SM/CHOL(1:1:1) bilayers (Fig. 6, bottom), demonstrating greater phaseseparation with the DHA-containing phospholipid. In all imagestaken it was evident that domains observed in the 16:0-22:6PE/SM/CHOL(1:1:1) bilayers were very large (>1 µm in size) andinterconnected compared to those (<1 µm in size) observedin the 16:0-18:1PE/SM/CHOL (1:1:1) membranes. The connectednature of the raft domains in the DHA-containing membranes,often extending beyond the image field, made comparison of raftsize between the two model membranes uncertain. Vesicles thatdid not fuse appear as bright spots on the images and are eliminatedin the calculations. There was a variation of 0.5–0.6nm in bilayer thickness for the two model membranes that wasdetermined by measuring the height difference from the exposedmica holes or from the edges of the bilayers. Giocondi et al.(2004)

suggested that changes in bilayer thickness from sampleto sample measured in this manner can be attributed to differencesin the hydration layer between the substrate and bilayers. Ina few places, the heights of some phase-separated domains couldbe up to 2.4 nm above the background bilayer. These structures,called "corrugated domains," have been reported by others insimilar AFM studies (Giocondi et al., 2004

) but were not includedin our calculations.

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FIGURE 6 Representative AFM images at 23°C of 16:0-18:1PE/SM/CHOL (1:1:1) (top) and 16:0-22:6PE/SM/CHOL (1:1:1) (bottom) supported bilayers with a z scale of 20 nm (color bar). The insets present the section profile corresponding to the white line on the image.

16:0-18:1PE is less detergent-soluble than 16:0-22:6PE in the presence of equimolar SM/CHOL in lipid vesicles
The detergent extraction method is widely utilized to assessthe presence of lipid microdomains in membranes and in factis a hallmark of lipid rafts (Edidin, 2003b

). We compared solubilizationof MLVs composed of 16:0-18:1PE/SM/CHOL (1:1:1) versus 16:0-22:6PE/SM/CHOL(1:1:1) to assess differences in phase separation between theOA- and DHA-containing PEs with the lipid-raft molecules SMand CHOL. Detergent-resistant studies were performed at 4°C,where most detergent solubility experiments have been conducted,and at 40°C to approximately mimic physiological temperature.Fig. 7 shows the percentage of lipid found in the detergent-solublefraction relative to the total amount of that lipid in the vesicles.Results are presented as the average + standard deviation (SD)from three separate experiments consisting of a minimum of foursamples. Less than 10% of SM or CHOL are found in the solublefractions for both 16:0-18:1PE/SM/CHOL (1:1:1) and 16:0-22:6PE/SM/CHOL(1:1:1) mixtures at 4°C (Fig. 7 a), which agrees with thenotion that these lipids are detergent-resistant. Increasingthe temperature to 40°C results in a higher percentage ofSM and CHOL in the DSM fractions for both samples (Fig. 7 b).The change is greatest for CHOL in 16:0-22:6PE/SM/CHOL (1:1:1)where $~$ 30% CHOL is detergent-solubilized but, nevertheless, SMand CHOL predominantly remain detergent-resistant. An increasein solubilization of SM/CHOL at higher temperature has beenreported by others (Gandhavadi et al., 2002

). Most notably,we observe that a significant difference exists in the percentageof 16:0-18:1PE versus 16:0-22:6PE species found in the DSM fractionsat both temperatures. Whereas the majority of the monounsaturatedphospholipid is detergent-insoluble, the opposite is true forthe polyunsaturated PE. At 4°C, $~$ 22% 16:0-18:1PE in contrastto $~$ 70% 16:0-22:6PE is found in the soluble fraction, demonstratinga threefold difference in phase separation between the two PElipids (Fig. 7 a). At 40°C, the differential is nearly twofold,with $~$ 40% of the 16:0-18:1PE and $~$ 78% of the 16:0-22:6PE specieslocated in the detergent-soluble fractions (Fig. 7 b). Increasingthe temperature results in greater solubilization of both PElipids as is the case with SM and CHOL.

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FIGURE 7 Percentage (mean + SD) of SM, CHOL, and PE found in the DSM fraction of Triton X-100 treated aqueous multilamellar dispersions of 16:0-18:1PE/SM/CHOL (1:1:1) (no pattern) or 16:0-22:6PE/SM/CHOL (1:1:1) (dense pattern) at (a) 4 and (b) 40°C. Each value is relative to the total amount of the specific lipid in both detergent-soluble and detergent-insoluble fractions. The values represent a minimum of four samples from three separate experiments. Supernatant lipids were recovered by HPTLC and quantified via charring (Materials and Methods).

OA and DHA are mostly detergent-solubilized in cells
We utilized detergent-resistant assays with neonatal cardiomyocytesto look for differences in the localization (raft versus non-raft)of OA and DHA in a cellular system. Sucrose gradients were collectedin 1-mL increments (top to bottom) and fractions 4–6 aredenoted as the DRM raft-rich fractions based on binding of ß-choleratoxin to the raft marker GM1 (Fig. 8 a). We specifically assesseddifferences in the localization of [³H]OA (Fig. 8 b) and [¹⁴C]DHA(Fig. 8 a) in neonatal cardiomyocytes. It is important to notethat most of the [³H]OA and [¹⁴C]DHA was found in the non-raftDSM fractions 8–12. Nevertheless, a significant differenceexists between the percentage of each fatty acid found in theDRM fractions. In the case of [³H]OA, 14.5 ± 2.6% ofthe radiolabel was found in the DRM fractions. In comparison,7.4 ± 0.9% of the [¹⁴C]DHA was located in the DRM fractions,demonstrating a nearly twofold difference between the monounsaturatedand polyunsaturated fatty acids. Although incorporation of freefatty acids into phospholipids with this method is well characterized(Munro, 2003

; Stulnig et al., 1998

), we verified incorporationof radiolabeled OA and DHA into phospholipids using HPTLC analysis.Most of the OA and DHA were incorporated into PCs and PEs withlesser amounts into other phospholipids (data not shown).

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FIGURE 8 Percentage (mean + SD) of (a) GM1, (b) [³H]OA, and (c) [¹⁴C]DHA in sucrose-gradient fractions of neonatal cardiomyocytes. Cells were incubated at 4°C in the presence of 1% Triton X-100, homogenized, and placed on a 5–40% sucrose gradient. After ultracentrifugation, fractions were collected in 1-mL increments from the top to bottom of the centrifuge tubes and analyzed (Materials and Methods). Values represent a minimum of three separate experiments.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSION ACKNOWLEDGEMENTS REFERENCES

We have previously suggested that polyunsaturation may triggerlipid phase separations affecting lipid raft structure and function(Shaikh et al., 2002

). The focus of this study was to furtherassess the effect of replacing a phospholipid-containing OAwith the beneficial ${omega}$ -3 fatty acid DHA on raft molecules. Weexamined phase behavior and molecular organization in 16:0-18:1PE-d₃₁/SM/CHOL(1:1:1) versus 16:0-22:6PE-d₃₁/SM/CHOL (1:1:1) model bilayermembranes using ²H NMR spectroscopy, DSC, AFM, and detergentextractions. In addition, we evaluated differences in phaseseparation of OA versus DHA from rafts using the biochemicaldetergent extraction method in cells.

Role of steric incompatibility between CHOL and DHA
²H NMR indicates cholesterol interacts less with 16:0-22:6PE-d₃₁than 16:0-18:1PE-d₃₁ in SM-containing mixtures. Spectral momentsevaluated at 40°C upon the incorporation of CHOL into 16:0-18:1PE-d₃₁/SM(1:1) and 16:0-22:6PE-d₃₁/SM (1:1) membranes translate to increasesof $~$ 61% and $~$ 26%, respectively, in order (Table 1). We recentlyestablished a reduced affinity of CHOL for 16:0-22:6PE in comparisonto 16:0-18:1PE in the absence of SM (Shaikh et al., 2003a).First moments derived from ²H NMR spectra revealed that addingequimolar CHOL to 16:0-18:1PE-d₃₁ broadened the T_m until itbecame unobservable. In contrast, the transition was detectedin 16:0-22:6PE-d₃₁/CHOL (1:1) and was relatively unperturbedrelative to when sterol was absent. Corroborating x-ray diffractionexperiments found a solubility of 32 ± 3 mol % for CHOLin 16:0-22:6PE membranes whereas 51 ± 3 mol % could beaccommodated in 16:0-18:1PE (Shaikh et al., 2003a). Thus, stericincompatibility between CHOL and the highly disordered PUFAchain in 16:0-22:6PE may serve as a molecular mechanism by whichlateral phase separations into l_o and l_d microdomains are promoted.

Evidence for unfavorable interactions between DHA-containingphospholipids and CHOL has been reported in other model systemsas well. Demel et al. (1972) and later Zerouga et al. (1995)demonstrated weak association between a DHA-containing PC andCHOL based upon percent condensation calculated for monolayersat the air-water interface. Additional support for a reducedaffinity between CHOL and DHA-containing phospholipids has comefrom a bilayer study by Huster et al. (1998) indicating thatCHOL maintains a closer contact with saturated acyl chains inheteroacid sn-1 saturated sn-2 polyunsaturated phospholipids.These researchers showed by two-dimensional NOESY ¹H NMR spectroscopywith magic angle spinning that the sterol displays higher chain-to-cholesterolcross-relaxation rates with saturated chains than with polyunsaturatedchains in mixed 18:0-22:6PC/CHOL bilayers, suggesting preferentialinteraction between CHOL and the saturated 18:0 sn-1 chain (Husteret al., 1998). By a combination of solid-state ²H NMR and x-raydiffraction techniques we have also demonstrated low sterolsolubility in PC and PE membranes containing PUFAs (Brzustowiczet al., 1999, 2002a,b; Shaikh et al., 2003a).

CHOL-OA interactions
Our ²H NMR data, on the contrary, give no indication that 16:0-18:1PEhas a low degree of affinity for cholesterol. The increase of $~$ 61% in average order parameter upon the introduction of equimolar cholesterol into 16:0-18:1PE-d₃₁/SM(1:1) bilayers (Table 1), furthermore, is greater than we sawin 16:0-18:1PE-d₃₁ bilayers where rose by 33% (Shaikh et al, 2003a). The implication is that the OA-containingPE does not phase separate well from the lipid-raft moleculesSM and CHOL in the 16:0-18:1PE/SM/CHOL (1:1:1) system comparedto 16:0-22:6PE/SM/CHOL (1:1:1). This conclusion regarding 16:0-18:1PEmay reflect the dependence upon composition and temperaturefound by others for lateral segregation into domains in PC/SM/CHOLmixtures (de Almeida et al., 2003; Veatch and Keller, 2003).A DSC and AFM study by Milhiet et al. (2002) found no evidencefor domains at ${chi}$ _CHOL $≥$ 0.33 in 16:0-18:1PC/SM (3:1) bilayers althoughphase separation was observed at ${chi}$ _CHOL $≤$ 0.33. As we examined onlya single CHOL content here, phase separation between 16:0-18:1PEand SM/CHOL domains may be possible at lower CHOL concentrationsor at different 16:0-18:1PE/SM ratios. In the absence of CHOL,the deconvolution of the exotherm in our DSC scans into twocomponents does suggest that phospholipid and sphingolipid phaseseparate in 16:0-18:1PE/SM (1:1) (Fig. 3 c, inset). A recentsolid-state NMR investigation concluded that 16:0-18:1PC doesnot phase separate from SM/CHOL raft domains (Aussenac et al.,2003). These researchers found that order parameters for ²H-labeledCHOL in 16:0-18:1PC/SM/CHOL (1:1:1) were between those of 16:0-18:1PC/CHOL(1:1) and SM/CHOL (1:1), implying that the sterol is in intimatecontact with both 16:0-18:1PC and SM in the mixed membrane.Explanations include homogeneous mixing and fast exchange oflabeled cholesterol between 16:0-18:1PC/CHOL and SM/CHOL microdomains.A higher partition coefficient of CHOL in an OA-containing PCin comparison to a DHA-containing PC was also recently reported.Using a novel vesicle-cyclodextrin system to measure CHOL'spartition coefficient in unilamellar vesicles, Niu and Litman(2002) measured a 2.6-fold higher partitioning of CHOL in 16:0-18:1PCcompared to 16:0-22:6PC.

Phase separation observed with AFM
Our AFM results with 16:0-18:1PE/SM/CHOL (1:1:1) show that mostof the bilayer is homogeneous in thickness with a few ( $~$ 26% ofthe total surface area) phase-separated domains rich in SM orSM/CHOL (Fig. 6). We propose that CHOL interacts with both SMand 16:0-18:1PE, which results in a homogenous l_o phase witha few SM- or SM/CHOL-rich light domains protruding from thebilayer surface. This finding is consistent with our ²H NMRand detergent-resistant observations that CHOL interacts stronglywith 16:0-18:1PE-d₃₁ in the presence of equimolar SM. In addition,²H NMR studies have shown that 16:0-18:1PE/CHOL can form anl_o phase (Pare and Lafleur, 1998). In the case of 16:0-22:6PE/SM/CHOL(1:1:1) bilayers (Fig. 6), more phase-separated light (SM- orSM/CHOL-rich) domains are observed ( $~$ 59% of the total surfacearea). The dark thinner domains are attributed to the l_d phaserich in 16:0-22:6PE. Again, this finding is consistent withour ²H NMR and detergent-resistant data that suggest enhancedphase separation in the presence of polyunsaturation. A continuingproblem in membrane structural studies is determining the actualsize of lipid domains. Although our earlier NMR work on mixedPCs is consistent with diffusion-mediated fast exchange of cholesterolbetween microdomains <160 Å in size (Brzustowicz etal., 2002b), our AFM measurements here identify domains in themicron range. Any attempt to reconcile this apparent discrepancymust take into account that, due to very different timescales,the two methods are inherently sensitive to inequivalent lengthscales. The timescale of the ²H NMR approach is $~$ 10^–5 s,whereas AFM is much slower. Our AFM images were obtained in $~$ 2 min, during which time lateral diffusion of lipid would preventobservation of individual microdomains. One possible explanationthat we are pursuing is that the very large domains observedwith AFM are actually composed of clusters of much smaller domainsimplied by NMR.

Detergent-solubilization studies in vesicles
Detergent-solubilization studies were conducted at 4 and 40°Cto further evaluate phase separations in our model membranesystems. They were undertaken at higher and lower temperaturebecause the validity of detergent extractions that are routinelyperformed at 4°C to assess phase separation has been questionedand may not reflect the phase state of the lipid mixture atphysiological temperature (Shogomori and Brown, 2003). However,our ²H NMR and DSC data for 16:0-18:1PE/SM/CHOL (1:1:1) and16:0-22:6PE/SM/CHOL (1:1:1) (Figs. 2 and 3) establish that eachmixture is liquid crystalline at both low and high temperatures.The results identify that $~$ 60–80% 16:0-18:1PE versus $~$ 20–30%16:0-22:6PE are found in the DRM fraction at either 4 or 40°C(Fig. 7). Although it is plausible that Triton may be inducingdomain formation (Heerklotz, 2002), our detergent extractionfinding is in agreement with our NMR observation that CHOL increasesthe order of both PEs in the presence of SM but exerts muchgreater effect on 16:0-18:1PE-d₃₁ than on 16:0-22:6PE-d₃₁ (Table 1and Fig. 3). The significant difference in the amount of 16:0-18:1PEin the DSM fraction compared to 16:0-22:6PE for both temperatures,moreover, suggests phase separation that is driven by the presenceof the polyunsaturated acyl chain in agreement with our AFMdata. The differences in phase separation are also correlatedto the differences in T_m of the two PEs examined, in accordwith previous findings (Ferguson, 1999; Shaikh et al., 2003b).Phase separation driven by the presence of acyl chain unsaturation,as assessed by detergent extraction, was identified in an 18:1-18:1PC/SM/CHOL(1:1:1) model system by McIntosh and co-workers (Gandhavadiet al., 2002; McIntosh et al., 2003). These researchers sawa greater proportion of 18:1-18:1PC in the DSM fraction at 4and 37°C in the presence of equimolar SM and CHOL, and suggestedthat mechanical properties of DRMs and DSMs may have implicationsfor peptide sorting (McIntosh et al., 2003).

Detergent-solubilization studies in cells
As seen in our model membrane studies, a significant differencein the amount of OA versus DHA was found in DRM fractions isolatedfrom cardiomyocytes. However, our cellular studies reveal thatthe vast majority of OA and DHA are localized in the DSMs, whereasour model membrane studies would predict that most of the OAwould be raft-localized in cells. This inconsistency suggeststhat our model membrane studies do not correlate perfectly withour cellular model. Perhaps a three-component lipid system doesnot realistically reflect the complex heterogeneities that mayarise in the plasma membrane due to interactions amongst variouslipids, proteins, and even the cytoskeleton. Although this suppositionhas validity, we believe that the discrepancy in the OA databetween model membranes and cells can be explained better ifone takes into account the limitations of the detergent extractionapproach. Lipid phase behavior is highly temperature-dependentand complicated in a real cell membrane that is composed ofhundreds of different lipid molecular species. Thus, the reductionin temperature could have resulted in changes in lipid organizationthat would be difficult to model in simple two- or three-componentvesicles. A recent study by Schuck et al. (2003) furthermoreshowed that different detergents show considerable differencesin their ability to solubilize membrane lipids and proteins.This underscores the difficulty of interpreting detergent extractionsas a tool for understanding membrane organization. These researcherssuggested that the presence of certain lipids or proteins inthe DRM fraction does not necessarily indicate an associationwith the same microdomain in the biological membrane (Schucket al., 2003). Another major limitation of the detergent-solubilizationtechnique is that partial solubilization may not be the resultof differences in solubility between microdomains but ratherdue to differences in the solubility of the two leaflets. PerhapsOA and DHA are localizing to different leaflets. Indeed Knappet al. (1994) reported that DHA is preferentially accepted intothe inner leaflet of PEs and phosphatidylserines of the erythrocyteplasma membrane. Further investigation into this matter is clearlyof interest. Finally, different cell lines may show differentresults. We examined changes in OA and DHA localization in MDA-MB-231breast cancer cells where differences were smaller than thosereported for cardiomyocytes (Shaikh et al., unpublished data).

Physiological relevance of DHA-lipid raft phase separations
Since ${omega}$ -3 fatty acids are increasingly being utilized clinicallyas adjuvant immunosuppressants in the treatment of inflammatorydiseases, it is becoming evident that PUFAs modulate immuneresponses by suppressing T-cell activation in lymphoid cells.The suggestion has been made that inhibition of T-cell signalingmay be mediated by modification of lipid raft microdomains uponincorporation of various PUFAs including eicosapentaenoic acid(20:5) and arachidonic acid (20:4) (Webb et al., 2000; Zeydaet al., 2002). Although relatively little is known about themolecular interactions between PUFAs and lipid rafts, a fewstudies have emerged to explain the physiological importanceof the PUFA-lipid raft relationship at a cellular level.

A recent investigation showed that acylated proteins found inlipid rafts were displaced due to the incorporation of eicosapentaenoicacid in Jurkat T cells (Stulnig et al., 2001). In another study,it was demonstrated that DHA stimulates phospholipase D1 activityin stimulated human peripheral blood mononuclear cells, whichmay be responsible for some of the DHA-induced immunosuppression(Diaz et al., 2002). These researchers found that phospholipaseD1 (PLD1), located in the DRM fractions of sucrose gradients,is lipid raft-localized in the absence of DHA treatment andthat its activity is impaired (Diaz et al., 2002). Treatmentof the peripheral blood mononuclear cells with DHA resultedin changing its localization from DRMs to DSMs and an increasein activity was observed. Both studies have suggested that alteredlipid raft formation may be responsible for the known inhibitoryeffects of PUFAs on T-cell activation. However, the molecularmechanism by which this occurs remains elusive.

In Fig. 9 we present a cartoon depiction of the molecular mechanismby which activity of proteins such as PLD1 may change upon incorporationof DHA into cells. We hypothesize that incorporation of a DHA-phospholipidresults in enhanced phase separation of the l_d-favoring, DHA-richphospholipids from the l_o lipid rafts, thereby changing thelocalization and activity of selected proteins. Phase separationis proposed to be triggered by the decreased solubility of CHOLin DHA-containing phospholipids (Brzustowicz et al., 2002a;Shaikh et al., 2003a). In the example depicted in Fig. 9, asthe DHA-phospholipid accumulates into the nonraft domain, CHOLis driven to the raft domain. The protein X, originally locatedin a raft where it is inactive, then partitions into the nonraft,DHA-rich domain where its conformation is altered resultingin enhanced activity. An example of a protein that may followthis path is PLD1 that upon DHA treatment is excluded from rafts.The accumulation of PLD1 in DHA-rich, nonraft domains activatesthe protein and disrupts signal transduction events, accountingfor the fatty acid's known immunosuppressive effects. DHA hasalso been implicated in influencing the activity of other proteinsincluding rhodopsin (Litman and Mitchell, 1996), protein kinaseC (Padma and Das, 1999), phospholipase C (Sanderson and Calder,1998), insulin receptor (McCallum and Epand, 1995), gamma-aminobutyrictype A receptor (Nabekura et al., 1998), and the nicotinic acetylcholinereceptor (Rankin et al., 1997).

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FIGURE 9 Cartoon depiction of DHA-induced alteration of plasma membrane lipid domain structure. The outer membrane leaflet is shown since it is here that the SM- and cholesterol-rich l_o (raft) domains exist in a background of nonraft bulk lipids. Upon the addition of a DHA-rich phospholipid, cholesterol is excluded from the nonraft (l_d) domains into the raft domains, increasing raft size and stability. In the example presented here, the inactive protein, X, initially found in the raft domain, is then recruited to the DHA-rich, nonraft domain where it undergoes a conformational change, resulting in its activation.

	CONCLUSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSION ACKNOWLEDGEMENTS REFERENCES

Our results identify major differences in the molecular interactionsof OA versus DHA with raft molecules. These findings providefurther evidence in support of the hypothesis that DHA-containingphospholipids will phase separate into DHA-rich, SM/CHOL-poorand DHA-poor, SM/CHOL-rich microdomains. Studies of DHA-lipidraft phase separations may contribute to understanding morecomplex signaling pathways involving proteins. Perhaps DHA exertsits beneficial health effects on numerous disease states includingdepression, heart disease, various cancers, schizophrenia, andarthritis by influencing lipid raft-mediated cell signalingevents.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

This work was supported by a grant from the National Institutesof Health (RO1CA57212).

Submitted on April 16, 2004; accepted for publication June 18, 2004.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

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