Fluorescence Energy Transfer Reveals Microdomain Formation at Physiological Temperatures in Lipid Mixtures Modeling the Outer Leaflet of the Plasma Membrane

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Fluorescence Energy Transfer Reveals Microdomain Formation at Physiological Temperatures in Lipid Mixtures Modeling the Outer Leaflet of the Plasma Membrane

John R. Silvius

Department of Biochemistry, McGill University, Montréal, Québec H3G 1Y6, Canada

Correspondence: Address reprint requests to John R. Silvius, Rm 8-19 McIntyre Bldg., 3655 rue Drummond, Montreal, Quebec H3G 1Y6, Canada. Tel.: 514-398-7267; Fax: 514-398-7384; E-mail: john.silvius{at}mcgill.ca.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

An approach is described using fluorescence resonance energytransfer (FRET) to detect inhomogeneity in lipid organization,on distance scales of the order of tens of nanometers or greater,in lipid bilayers. This approach compares the efficiency ofenergy transfer between two matched fluorescent lipid donors,differing in their affinities for ordered versus disorderedregions of the bilayer, and an acceptor lipid that distributespreferentially into disordered regions. Inhomogeneities in bilayerorganization, on spatial scales of tens of nanometers or greater,are detected as a marked difference in the efficiencies of quenchingof fluorescence of the two donor species by the acceptor. Usinga novel pair of 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD)-labeledtetraacyl lipids as donor species with a rhodaminyl-labeledacceptor, this strategy faithfully reports homo- versus inhomogeneousmixing in each of several lipid bilayer systems whose organizationon the FRET distance scale can be predicted from previous findings.Interestingly, however, the present FRET method reports clearevidence of inhomogeneity in the organization of mixtures combiningsphingomyelin or saturated phospholipids with unsaturated phospholipidsand physiological proportions of cholesterol, even at physiologicaltemperatures where these systems have been reported to appearhomogeneous by fluorescence microscopy. These results indicatethat under physiological conditions, lipid mixtures mimickingthe lipid composition of the outer leaflet of the plasma membranecan form domains on a spatial scale comparable to that inferredfor the dimensions of lipid rafts in biological membranes.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

The plasma membrane, and at least some other membranes, of animaland fungal cells exhibit segregation of cholesterol- and sphingolipid-enricheddomains (e.g., lipid rafts and caveolae) whose distinctnessfrom other regions of the membrane appears to support importantaspects of membrane function (for reviews see Simons and Ikonen,1997; Anderson, 1998; Brown and London, 1998; Simons and Toomre,2000; Kurzchalia and Parton, 1999; Anderson and Jacobson, 2002).Studies using model membranes have suggested that a centralelement in the formation of lipid rafts and related membranemicrodomains is the tendency of sphingolipids, which carry mainlysaturated acyl chains, to demix from unsaturated membrane phospholipidsin the presence of cholesterol (Schroeder et al., 1994; Ahmedet al., 1997; Brown, 1998; Rietveld and Simons, 1998; Xu etal., 2001). Consistent with this observation, reduction of plasmamembrane cholesterol levels in mammalian cells appears to perturbmany aspects of raft organization and function (Furuchi andAnderson, 1998; Pike and Miller, 1998; Sheets et al., 1999;Roy et al., 1999; Ushio-Fukai et al., 2001; Pike and Casey,2002; Matveev and Smart, 2002; Smart and Anderson, 2002).

Fluorescence measurements have previously been used to obtainevidence for an inhomogeneous lateral organization of lipidson different spatial scales in ternary mixtures combining cholesterol,phospholipids with low gel-to-liquid crystalline transitiontemperatures, and high-melting phospho- or sphingolipids. Fluorescence-microscopicstudies (Dietrich et al., 2001a,b; Samsonov et al., 2001; Feigensonand Buboltz, 2001; Veatch and Keller, 2002, 2003) have revealedsegregation of fluid-state domains of micron dimensions undercertain conditions in vesicles with such compositions. However,in systems of this type that incorporate levels of cholesterolcomparable to those found in mammalian cell plasma membranes,microscopically visible domains are typically not observed atphysiological temperatures (Dietrich et al., 2001a; Veatch andKeller, 2002, 2003). Measurements of quenching of the fluorescenceof membrane-incorporated probes by spin-labeled or brominatedlipids (Silvius, 1992; Silvius et al., 1996; Ahmed et al., 1997;Wang and Silvius, 2000, 2001, 2003; Wang et al., 2000, 2001;Xu and London, 2000; Xu et al., 2001; London, 2002) have howeverindicated that even at physiological temperatures, similar systemsexhibit an inhomogeneous lateral organization of lipids on adistance scale of the order of nearest-neighbor separations( ${approx}$ 1 nm).

In principle, fluorescence could be used to monitor inhomogeneityin the organization of bilayers on an intermediate scale ofdistances ( ${approx}$ tens of nanometers) through measurements of fluorescenceresonance energy transfer (FRET). This possibility is attractivebecause lipid "raft" microdomains in biological membranes appearto have dimensions as small as a few tens of nanometers (Pralleet al., 2000; Varma and Mayor, 1998), and cholesterol-rich clusterswith slightly smaller dimensions have also been proposed toexist in biological membranes (Radhakrishnan et al., 2000; Andersonand Jacobson, 2002). FRET has in fact been successfully employedto monitor lipid phase separations in binary mixtures of phospholipids(Pedersen et al., 1996; Stillwell et al., 2000; Leidy et al.,2001). However, to date FRET measurements have seen only verylimited use to monitor the lateral organization of lipids incholesterol-containing systems (Feigenson and Buboltz, 2001).This reflects at least in part the fact that it has proven difficultto design fluorescence probes that report consistently and ina straightforward manner the occurrence of inhomogeneity inthe lateral organization of lipids in such systems (Stillwellet al., 2000).

This report describes the identification and use of new combinationsof fluorescent probes that allow FRET-based detection of inhomogeneityin lipid lateral organization in a variety of cholesterol-containingsystems. This approach reliably reports inhomogeneities in thelateral distributions of lipids in cholesterol-containing systemsthat have previously been shown by microscopy to exhibit large-scalesegregation of fluid domains. However, the FRET assay also indicatesthat in such systems inhomogeneity in lipid distributions, ona spatial scale of the order of that reported for raft domainsin biological membranes (tens of nanometers or greater), persistsat physiological temperatures and cholesterol contents wherelarge (micron-size) segregated domains have not been observed.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Materials
Synthetic phospholipids, bovine brain sphingomyelin, and cholesterolwere purchased from Avanti Polar Lipids (Alabaster, AL). 7-Nitrobenz-2-oxa-1,3-diazol-4-yl-(NBD-), lissamine rhodamine B sulfonyl- (Rho-), bimanylthioacetyl-(Bimta-), and fluorescein-labeled phosphatidylethanolamines(PEs) were synthesized as described previously (Monti et al.,1978; Struck et al., 1981; Wang et al., 2000). 1,2-Dioleoylphosphatidyl-N,N-dimethyl-N-(2,2,6,6-tetramethyl-y-piperidinyl)-ethanolamine(TEMPO-DOPC) and the bimane-labeled bis(phosphatidylethanolamido)mercaptosuccinylconjugates DOBDO and DSBDS (Fig. 1) were also synthesized asdiscussed elsewhere (Wang et al., 2000). N-(7-dimethylaminocoumarinyl-4-acetyl)-(DMCA-) and fluorescein-labeled PEs were synthesized by reacting5 µmol PE with 10 µmol each of triethylamine andeither 7-dimethylaminocoumarin-4-acetic acid succinimidyl esteror 5-(and 6-)carboxyfluorescein succinimidyl ester in 0.25 ml9:1 CH₂Cl₂ for 3 h at 25°C. The products of these reactionswere purified by preparative thin-layer chromatography on silicagel 60 plates developed in 50:15:5:5:2 CH₂Cl₂/acetone/methanol/aceticacid/H₂O.

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FIGURE 1 Structures of the tetraacyl NBD- and bimanyl-labeled phospholipid conjugates examined as potential FRET donor species in this study.

The NBD-labeled phosphatidylserine-phosphatidylethanolamineconjugates shown in Fig. 1 (DONDO and DSNDS) were synthesizedas follows. Dioleoyl or distearoyl phosphatidylserine (PS) wasconverted to its N-t-butoxycarbonyl (Boc) derivative by reactionwith (2-tert-butoxycarbonyloxyimino)-2-phenylacetonitrile indry methylene chloride/triethylamine (99:1) for 6 h at 22°C(for dioleoyl PS) or 40°C (for distearoyl PS), respectively.After purification by preparative thin-layer chromatography(TLC) on silica gel 60 plates, developed in 50:12:4:4:1 CH₂Cl₂/acetone/methanol/aceticacid/H₂O, the Boc-PS products were coupled to phosphatidylethanolamineswith the same acyl chains in 3:1 dry CH₂Cl₂/dry dimethylformamidein the presence of 5, 5, 80, and 30 equivalents, respectively,of dicyclohexylcarbodiimide, N-hydroxysuccinimide, diisopropylethylamine,and trifluoroacetic acid (TFA). After incubation for 6 h at25°C or 45°C, respectively, for the oleoyl- and stearoyl-substitutedspecies, the reaction mixtures were partitioned between CH₂Cl₂and 1:1 methanol/0.1 M aqueous HCOONa, pH 3, and the lower phaseswere washed twice with the same mixture of methanol and aqueousHCOONa and dried, first under N₂ and then under high vacuumto remove residual dimethylformamide. The Boc-protected conjugateswere purified by preparative TLC in 50:12:4:4:1 CH₂Cl₂/acetone/methanol/aceticacid/H₂O, then N-deprotected by incubating in 50:50:3 (v/v/v)TFA/CH₂Cl₂/dimethylsulfide for 2 h at 0°C, adding the incubationmixture to a chilled mixture of CH₂Cl₂ and triethylamine (inquantities sufficient to neutralize the trifluoroacetic acid)and recovering by partitioning between CH₂Cl₂ and 1:1 methanol/0.1M HCOONa as described above. The N-deprotected conjugates werefinally labeled with NBD-fluoride (in 90:10:1 CH₂Cl₂/methanol/triethylamine,for 30 min at 20°C) and purified by preparative TLC as describedfor the corresponding Boc-protected conjugates.

Fluorescence assay of gel/fluid phase partitioning of lipid probes
Lipid samples (25 nmol total phospholipid, including 0.5 mol%fluorescent lipid) were prepared in 2:1 (v/v) CH₂Cl₂/CH₃OH,then dried down under nitrogen with warming to 50–55°C.After further drying under high vacuum for 3–6 h, themixtures were dispersed by vortexing at 55°C in 3 ml buffer(100 mM KCl, 10 mM 3-(N-morpholino)propanesulfonic acid, 1 mMethylenediaminetetraacetic acid, pH 7.0). Samples were thensealed under argon, slowly cooled (at <0.2°C/min) from55°C to 20°C, and incubated at this temperature for96 h. Sample fluorescence was read at the latter temperaturein a Perkin-Elmer LS-5 spectrofluorometer with a thermostattedcuvette holder, using the following excitation and emissionwavelengths (slitwidths): 390/468 nm (10/10 nm) for bimane-labeledlipids, 400/460 nm (10/10 nm) for DMCA-labeled lipids, 470/538nm (10/10 nm) for NBD-labeled lipids, 494/520 nm (5/5 nm) forfluorescein-labeled lipids, 525/596 nm (10/10 nm) for rhodamine-labeledlipids, and 517/563 nm (5/5 nm) for DiIC₁₆(3) and DiIC₁₈(3).After this initial fluorescence reading the samples were mixedwith 150 µl 20% Triton X-100, heated to 55–60°Cfor 15 min, vortexed and bath-sonicated for 10 s each, and finallycooled to 20°C before remeasuring the fluorescence. Normalizedfluorescence values F_N were calculated by dividing the fluorescenceof each sample by the fluorescence measured after Triton solubilization,with suitable blank corrections in each case. Similar resultswere obtained for vesicles prepared by ethanol dilution as describedin the following section.

The relative affinities of fluorescent lipids for the gel versusthe fluid phase in dipalmitoylphosphatidylcholine (DPPC)/TEMPO-DOPCbilayers at 20°C were determined by fitting the quenchingcurves (plots of normalized fluorescence versus the molar percentageof TEMPO-DOPC) within the region of phase separation to theequation

(1)
where %Q isthe molar percentage of TEMPO-DOPC in the bilayer, %Q_gel and%Q_fluid define the limiting compositions for the region of phaseseparation (roughly 5 mol% and 65 mol% TEMPO-DOPC, respectively),F_N^gel and F_N^fluid are the (fitted) values of F_N for molar percentagesof quencher equal to %Q_gel and %Q_fluid, respectively, and K_pis the gel/fluid phase partition coefficient.

FRET measurements of inhomogeneity in lipid bilayers
Dried cholesterol/phospholipid mixtures (25 nmol/sample) containing0.3 mol% Rho-diphytanoyl PE and 0.5 mol% of either DSNDS orDONDO were prepared as described above. To compare optimallythe fluorescence of DONDO and DSNDS in vesicles of a given composition,a quantity of lipids (including Rho-PE) sufficient to preparesix samples of a given composition, but without any NBD-labeledprobe, was first mixed in solvent. Replicate aliquots of 25nmol lipid were then dispensed from this mixture, adding DONDOto three of the samples and DSNDS to the others before drying.The dried lipid mixtures were redissolved at 55°C in 30µl ethanol, then rapidly mixed (by vortexing) with 3 mlbuffer prewarmed to 55°C. Samples were then sealed underargon, slowly cooled (at <0.2°C/min) from 55°C tothe desired experimental temperature, and finally incubatedat the latter temperature for 24 h (for samples examined at37°C) or 48 h (for samples analyzed at lower temperatures).Vesicles prepared in this manner from DOPC/sphingomyelin/cholesterolmixtures (in varying proportions) and labeled with NBD-dioleoylPE (1 mol%) typically showed a rapid quenching of fluorescenceby 15–35% upon addition of the impermeant reducing agentsodium dithionite (5 mM). Since dithionite rapidly reduces (andhence quenches) only NBD-labeled lipid molecules exposed atthe extravesicular surface (McIntyre and Sleight, 1991), thesepreparations thus appear to contain predominantly vesicles comprisingfrom one to a few lamellae.

The ethanol-dilution method just outlined was used for the FRETexperiments presented in this study to promote homogeneous incorporationof cholesterol into vesicles with even relatively high sterolcontents (Feigenson and Buboltz, 2001). In a limited numberof experiments (not shown), FRET measurements were carried outusing vesicles (containing $<=$ 33 mol% cholesterol) that were preparedby vortexing dried lipid films into buffer as described in theprevious section. The results of these latter experiments werequalitatively very consistent with those obtained using vesiclesprepared by ethanol dilution.

The normalized fluorescence of samples doubly labeled with DSNDSor DONDO and Rho-diphytanyol PE, prepared as just outlined,was determined from readings taken before and after Triton solubilizationas described above. Normalized fluorescence values were determinedsimilarly for control samples prepared without Rho-PE. The correctedfluorescence ratio (R_fl^cor) of DSNDS versus DONDO probes inbilayers of a given composition was determined from these dataas

(2)
where the samplesdesignated +Acc and -Acc are those containing the indicateddonor species with or without acceptor, respectively. In mostcases the normalized fluorescence values measured for DONDOversus DSNDS agreed to within 2–4% in bilayers of a givencomposition (the only significant exception is illustrated inthe inset to Fig. 8 B, where for some compositions discrepanciesof up to 7–8% were observed). FRET experiments were repeatedfrom two to five times for each system examined; data shownare from representative experiments in each case.

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FIGURE 8 Corrected fluorescence ratios R_fl^cor (mean ± SD determined for triplicate sets of samples) measured for DONDO versus DSNDS in bilayers combining cholesterol with DOPC and phosphatidylcholines with higher gel/fluid transition temperatures. For each sample the content of DOPC is specified as its molar percentage in the total phospholipid fraction, i.e., as (100% x (moles DOPC)/(moles total phosphatidylcholine)). (A) Samples combining DPPC and DOPC with 33 mol% or (inset) 50 mol% cholesterol at 37°C. (B) Samples combining DMPC and DOPC with 33 mol% cholesterol at 20°C; (B, inset) identical samples prepared without the rhodaminyl-PE acceptor, showing the ratio of the normalized fluorescence values measured for DONDO and DSNDS. (C) Samples combining DMPC and DOPC with 50 mol% cholesterol or (inset) 0 mol% cholesterol at 37°C. (D) Samples combining DOPC and SOPC with 33 mol% cholesterol or (inset) DOPC and SOPC alone at 37°C.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

The general strategy that was explored to monitor inhomogeneityof lipid distributions by FRET in cholesterol-containing systemsis illustrated in Fig. 2. A matched pair of fluorescent donorlipids is utilized, differing only in the donor acyl chains,such that one donor species distributes with high selectivityinto disordered domains within the bilayer whereas the secondshows substantial affinity for ordered domains. These donorspecies are combined, in bilayers of a given composition, withan energy-transfer acceptor that partitions with high selectivityinto disordered domains. In homogeneous lipid bilayers containinga given concentration of the acceptor species, quenching ofthe fluorescence of either donor species by the acceptor willbe equally efficient, and the corrected fluorescence ratio R_fl^cordefined in Eq. 2 will have a value of unity. By contrast, inbilayers exhibiting inhomogeneous lateral distributions of thelipid species (on a spatial scale of tens of nanometers or greater),such that regions of greater and lesser lipid order coexist,the (disordered domain-preferring) acceptor will quench moreefficiently the fluorescence of the donor species that prefersdisordered domains. In this case the corrected fluorescenceratio R_fl^cor will show a value significantly less than unity.

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FIGURE 2 General strategy explored in this study to detect lateral inhomogeneity in lipid bilayer organization. An acceptor probe A, which shows a strong preference for less ordered regions of the bilayer, is combined in replicate samples with either of two matched donor species, D1 and D2. D1 and D2 are identical save for their acyl chains, which for probe D1 confer a strong preference for less ordered domains but for probe D2 confer a substantial affinity for more ordered regions of the bilayer. In bilayers where regions of greater and lesser order coexist, the donor species D1 and the acceptor species A will be coenriched in the less ordered regions of the bilayer (panel A). By contrast, a significant fraction of the donor species D2 will distribute into more ordered regions of the bilayer where the local concentration of acceptor species is very low (panel B). Heterogeneity in the lateral organization of the bilayer (specifically, the existence of more and less ordered regions with dimensions of the order of the Förster length R_o or greater) can thus be detected by comparing the relative efficiencies of energy transfer in replicate samples combining the acceptor species with donor D1 versus D2.

Successful exploitation of the above strategy requires firstthat the two matched donor species exhibit strongly differingaffinities for ordered versus disordered lipid domains, andsecond that the acceptor species partitions with high selectivityinto disordered domains. Initial experiments were thus undertakento identify fluorescent-labeled lipids that fulfill these criteria.

Relative affinities of different fluorescent lipids for gel-state lipid domains
A key requirement of the above strategy is the use of pairedfluorescent donor lipids, (only) one of which partitions withsignificant affinity into ordered lipid domains. To identifyfluorescent-labeled lipids that can fulfill the latter criterion,the fluorescence-quenching approach developed by Feigenson andcolleagues (London and Feigenson, 1981; Huang et al., 1988)was used to measure the affinities of various fluorescent moleculesfor gel versus fluid domains in phase-separated binary lipidmixtures. In this approach the normalized fluorescence for agiven fluorescent species is measured in bilayers combiningvarying molar proportions of a gel phase-forming lipid (here,DPPC) and a fluid phase-forming quencher lipid (here, TEMPO-DOPC)that phase-separates from the saturated species at the experimentaltemperature. Examples of quenching curves thereby obtained areshown in Fig. 3 A. Quenching curves that show upward (/downward)concavity over the region of phase separation (ranging from $~$ 5 to 65 mol% TEMPO-DOPC at the experimental temperature of 20°C)indicate preferential partitioning into fluid- (/gel-) phaseregions of the bilayer. As discussed previously (London andFeigenson, 1981; Huang et al., 1988) and as illustrated in theinset to Fig. 3 A, by fitting such experimental quenching curvesin the region of phase separation, it is possible to determinethe gel/fluid phase partition coefficient (K_p(gel/fluid)) forvarious fluorescent lipids.

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FIGURE 3 (A) Quenching curves showing the variation of the normalized fluorescence F_N (defined in Eq. 1) with the molar percentage of TEMPO-DOPC in DPPC/TEMPO-DOPC bilayers at 20°C for ( ${blacktriangleup}$ ) DSNDS, ( ${diamondsuit}$ ) NBD-distearoyl PE, and ( ${circ}$ ) DiIC₁₈(3). Samples were prepared and incubated, and fluorescence readings taken subsequently, as described in Materials and Methods. Data shown are from a single representative experiment. (A, inset) Fits of the data from panel A to Eq. 1 to determine the gel/fluid phase partition coefficient K_p for the different fluorescent lipids. To facilitate comparison the fitted curves have been scaled to values of unity and zero, respectively, at the right- and left-hand boundaries of the region of phase separation (estimated respectively as 5 mol% and 65% TEMPO-DOPC). (B) Quenching curves for ( ${blacktriangleup}$ ) DSNDS, ( ${diamondsuit}$ ) NBD-distearoyl PE, and ( ${circ}$ ) DiIC₁₈(3) in sphingomyelin/TEMPO-DOPC/(33 mol% cholesterol) bilayers at 20°C. To facilitate comparison the quenching curves have been normalized to a value of unity for bilayers containing 0 mol% TEMPO-DOPC. The x axis represents the molar percentage of TEMPO-DOPC in the phospholipid fraction. Other experimental conditions were as for panel A.

In Table 1 are listed the values of K_p(gel/fluid) determinedas just described for a variety of fluorescent lipids in theDPPC/TEMPO-DOPC system. A variety of headgroup-labeled fluorescentlipids and lipid analogs bearing two saturated 18-carbon chains,including bimane-, fluorescein-, NBD-, and rhodaminyl-PE, andindocyanine probes, partition preferentially into the fluidphase in this system. Probes with saturated 16-carbon chainsshow significantly lower affinity for gel-state domains, inagreement with previous observations (Spink et al., 1990

; Wanget al., 2000

). Increasing the acyl chain length of NBD-PE fromdi-18:0 to di-20:0 does not however enhance further affinityfor the gel state (Table 1). This result is consistent withother findings that partitioning of lipid probes into ordereddomains does not increase monotonically with increasing chainlength (Spink et al., 1990

; Wang et al., 2000

). However, lipidconjugates bearing four stearoyl chains (DSNDS and DSBDS, withthe general structures shown in Fig. 1) show a significantlygreater affinity for the gel phase than do distearoyl speciesbearing the same fluorescent group (Table 1). Similar resultswere obtained using sphingomyelin/TEMPO-DOPC mixtures at 20°C(not shown). The tetrastearoyl lipid conjugates also appearto show a significant affinity for ordered domains in mixturescombining DOPC and sphingomyelin with 33 mol% cholesterol, asillustrated in Fig. 3 B (compare the almost zero concavity ofthe quenching curve for the DSNDS probe to the marked upwardconcavity of the quenching curves for NBD-distearoyl PE andDiIC₁₈(3)). In contrast to the behavior of DSNDS, as expectedthe NBD-labeled tetraunsaturated species DONDO (structure shownin Fig. 1) is effectively excluded from the gel phase in thesesystems, as illustrated by the data in Table 1. The branched-chainspecies Rho-diphytanoyl PE also showed a very high preferencefor diphytanoyl fluid (liquid-disordered) over gel-phase domains(Table 1).

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TABLE 1 Values of gel/fluid phase partition coefficients (K_p) for fluorescent lipids in DPPC/TEMPO-DOPC bilayers at 20°C

FRET measurements of inhomogeneity in cholesterol-containing bilayers
Based on the findings presented above, further experiments exploredthe use of the matched donor species DONDO/DSNDS and the acceptorRho-diphytanoyl PE to probe for inhomogeneity of lipid distributionsin mixed-lipid bilayers. As illustrated in Fig. 4, in homogeneousDOPC bilayers at 37°C the fluorescence of the two donorspecies is quenched with identical efficiency by the rhodamine-labeledacceptor. The same is true for these donor species in 2:1 (mol/mol)DOPC/cholesterol bilayers (Fig. 4, inset). Using the analysisdescribed by Wolber and Hudson (1979)

, an apparent Försterenergy-transfer length R_o of 69–71 Å was calculatedfor these donor/acceptor pairs on the assumption that energytransfer occurs between fluorescent lipids in the same bilayerleaflet. Considering potential quenching contributions fromthe trans leaflet of the bilayer (Fung and Stryer, 1978

; Wolberand Hudson, 1979

), the true value of R_o is estimated to be $~$ 60Å for the combination of DONDO or DSNDS with Rho-diphytanoylPE. This is similar to the R_o value of $~$ 56 Å estimatedby Connor and Schroit (1987)

for the combination of an NBD-labeledphosphatidylcholine and a rhodaminyl-labeled phosphatidylethanolaminein DOPC vesicles.

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FIGURE 4 Quenching of fluorescence of (•) DONDO and ( ${circ}$ ) DSNDS at 37°C in DOPC bilayers containing the indicated molar percentages of Rho-diphytanoyl PE. (Inset) Quenching of the fluorescence of the same species in 2:1 (mol/mol) DOPC/cholesterol bilayers at 37°C. Quenching curves have been scaled to a value of unity at 0 mol% Rho-PE; the unscaled quenching curves were likewise superimposable for DONDO and DSNDS in DOPC bilayers but were slightly discrepant (by roughly 2% at 0 mol% Rho-PE) in DOPC/cholesterol bilayers. Other experimental data were as for Fig. 2.

DONDO and DSNDS were used in combination with Rho-diphytanoylPE to examine the homo- or inhomogeneity of lipid mixing at37°C in bilayers combining brain sphingomyelin, dipentadecanoylPC, or DOPC with increasing proportions of cholesterol. Lipidsamples of a given composition were prepared containing 0.5mol% of either DONDO or DSNDS together with either 0 or 0.3mol% Rho-diphytanoyl PE. The normalized fluorescence intensitiesmeasured for these samples were used to calculate the correctedratio of DONDO to DSNDS fluorescence (R_fl^cor) as described inMaterials and Methods and defined in Eq. 2. As shown in Fig.5 A, in sphingomyelin/cholesterol bilayers at 37°C, thevalue of R_fl^cor progressively decreases from unity as the proportionof cholesterol increases up to 30–35 mol%, then graduallyincreases again as the proportion of cholesterol increases further.Similar behavior was observed at 37°C (not shown) for mixturesof cholesterol and dipentadecanoyl PC (used in place of DPPCbecause it forms a fluid phase at 37°C even without cholesterol).This behavior indicates that cholesterol promotes an inhomogeneouslateral organization in bilayers in which it is combined withsphingomyelin or saturated PCs above their phase transitiontemperature, in agreement with the conclusions of previous studiesusing other experimental approaches (Vist and Davis, 1990

; Huanget al., 1993

; Sankaram and Thompson, 1990

, 1991

; McMullen andMcElhaney, 1995

). It appears that at least on a spatial scaleof tens of nanometers, cholesterol induces a laterally inhomogeneousdistribution of lipids in these systems over a wide range ofsterol concentrations. By contrast, the value of the correctedfluorescence ratio does not vary significantly from unity inbilayers combining DOPC with varying proportions of cholesterol(Fig. 5 B).

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FIGURE 5 Corrected fluorescence ratios R_fl^cor, defined as in Eq. 2, measured for DONDO versus DSNDS at 37°C in bilayers combining brain sphingomyelin (A) or DOPC (B) with the indicated molar percentages of cholesterol. R_fl^cor values shown (mean ± SD) were determined for triplicate sets of samples, prepared with or without the Rho-diphytanoyl PE acceptor (0.3 mol%) and containing 0.5 mol% of either DONDO or DSNDS, as described in Materials and Methods.

Experiments illustrated in Fig. 6 were carried out to examinethe homo- or inhomogeneity of lipid mixing in sphingomyelin/DOPC/cholesterolmixtures as a function of temperature and composition. As shownin Fig. 6 A, at 20°C in bilayers combining 33 mol% cholesterolwith brain sphingomyelin and DOPC in varying relative proportions,the value of the corrected fluorescence ratio is substantiallyless than unity over a wide range of sphingomyelin contents(Fig. 6 A). At 30°C or 37°C the value of R_fl^cor is alsosubstantially less than unity over a wide range of bilayer contentsof sphingomyelin relative to DOPC (Fig. 6, B and C), althoughthe magnitude of this divergence gradually decreases with increasingtemperature. Previous fluorescence-microscopic experiments haveshown that mixtures containing equimolar proportions of thesethree lipids show segregation of micron-size liquid domainsat temperatures below $~$ 25°C but appear homogeneous at highertemperatures (Dietrich et al., 2001a

; Veatch and Keller, 2003

).By contrast, the present results indicate that the lateral organizationof lipids in such mixtures remains markedly inhomogeneous onthe finer scale of distances sampled by FRET, even at physiologicaltemperatures. Raising the proportion of cholesterol to 50 mol%reduces but does not abolish the deviation of the correctedfluorescence ratio from unity in sphingomyelin/DOPC mixtures,even at 37°C (Fig. 6 D). By contrast, for cholesterol-freemixtures of sphingomyelin and DOPC at 37°C, the correctedfluorescence ratio is essentially equal to unity over the fullrange of compositions (Fig. 6 D, inset).

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FIGURE 6 Corrected fluorescence ratios R_fl^cor (mean ± SD determined for triplicate sets of samples) measured for DONDO versus DSNDS in sphingomyelin/DOPC/cholesterol bilayers. For cholesterol-containing samples, the content of DOPC is specified as its molar percentage in the total phospholipid fraction, i.e., as (100% x (moles DOPC)/(moles DOPC + moles sphingomyelin)). (A–C) Samples combining sphingomyelin and DOPC in varying proportions with 33 mol% cholesterol at 20°C (A), 30°C (B), or 37°C (C). (D) Samples combining sphingomyelin and DOPC in varying proportions with 50 mol% cholesterol at 37°C. (D, inset) Cholesterol-free samples combining sphingomyelin and DOPC in the indicated proportions at 37°C. R_fl^cor values shown (mean ± SD) were determined as described in the legend to Fig. 5.

The majority of phospholipids in mammalian cells carry one saturatedand one unsaturated acyl chain. It was thus of interest to determinewhether results similar to those just described would be observedin bilayers where the dioleoyl PC component was replaced by(saturated/unsaturated) mixed-acyl lipids. At 37°C mixturescombining sphingomyelin and 1-stearoyl-2-oleoyl phosphatidylcholine(SOPC) with 33 mol% cholesterol show inhomogeneous mixing overa wide range of sphingomyelin contents (Fig. 7 A). Mixturescombining sphingomyelin and 1-palmitoyl-2-linoleoyl PC with33 mol% cholesterol also show inhomogeneous mixing at 37°C(Fig. 7 B).

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FIGURE 7 Corrected fluorescence ratios R_fl^cor (mean ± SD determined for triplicate sets of samples) measured for DONDO versus DSNDS in bilayers combining sphingomyelin and 33 mol% cholesterol with SOPC (A) or 1-stearoyl-2-linoleoyl PC (B). For each sample the content of DOPC is specified as its molar percentage in the total phospholipid fraction, i.e., as (100% x (moles DOPC)/(moles DOPC + moles sphingomyelin)). R_fl^cor values shown (mean ± SD) were determined as described in the legend to Fig. 5.

The above FRET approach was finally used to investigate thepossible occurrence of laterally inhomogeneous lipid mixingin systems combining DOPC with various higher-melting phosphatidylcholinesand cholesterol. Mixtures combining 33 mol% cholesterol andDOPC with DPPC show marked inhomogeneity of mixing at 37°C(Fig. 8 A). Inhomogeneity is still apparent in this system evenat 50 mol% cholesterol (Fig. 8 A, inset), although the differencesin the fluorescence of the two donor probes are reduced. Bilayerscombining DOPC with 1,2-dimyristoylphosphatidyl-choline (DMPC)and containing 33 mol% cholesterol also show substantial inhomogeneityat 20°C (Fig. 8 B) or at 37°C (not shown). Even in thepresence of 50 mol% cholesterol and at 37°C, DMPC/DOPC mixturesshow inhomogeneous mixing (Fig. 8 C). By contrast, essentiallyhomogeneous mixing is seen for DMPC/DOPC bilayers at 37°Cin the absence of cholesterol (Fig. 8 C, inset). These findingsprovide evidence for cholesterol-promoted inhomogeneities inbilayer organization in the above systems (on a spatial scaleof at least tens of nanometers) that persist even at physiologicaltemperatures. Fluorescence-microscopic studies have reportedformation of large (micron-size) segregated domains in DPPC/DOPC/cholesteroland DMPC/DOPC/cholesterol mixtures at 20°C, which howevervanish at temperatures $>=$ 30°C (Veatch and Keller,2002

). In contrast to the behavior observed here for mixturesof DOPC and cholesterol with saturated phospholipids, at 37°C,mixtures of DOPC and SOPC containing either 0 or 33 mol% cholesterolshow apparently homogeneous mixing (Fig. 8 D and inset).

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

The FRET-based strategy used here was explored to allow detectionof inhomogeneities in the organization of lipid bilayers (vesicles)on a spatial scale intermediate between that of fluorescencemicroscopy (micron or just-submicron dimensions) and that probedby methods based on quenching of bilayer-incorporated fluorophoresby brominated or spin-labeled lipids (approaching nearest-neighbordistances, i.e., $~$ 1–2 nm). As noted previously (Feigensonand Buboltz, 2001), in models in which FRET acceptors are postulatedto be excluded from the immediate vicinity of donor moleculeswithin a surface, the efficiency of FRET is predicted to bemost sensitive to the diameter of the exclusion domain whenthe latter is roughly 1–4 times the characteristic energy-transferlength R_o (Wolber and Hudson, 1979; Dewey and Hammes, 1980;Zimet et al., 1995). It can thus be (crudely) estimated thatthe DONDO/DSNDS/Rho-PE probe combinations examined here, withan R_o value of $~$ 6 nm, can detect inhomogeneities in the lateralorganization of lipids within a bilayer when the spatial scaleof such inhomogeneities is on the order of tens of nanometersor greater. This is similar to the dimensions suggested forlipid rafts in biological membranes (Varma and Mayor, 1998;Pralle et al., 2000) and for cholesterol-induced lipid clustersthat have been hypothesized to play important roles in membraneorganization and function (Anderson and Jacobson, 2002). Atpresent, few experimental methods are available to characterizethe organization of lipid bilayers on this spatial scale.

The FRET approach employed here correctly reports a homogeneousorganization of the bilayer (on a spatial scale of tens of nanometersor greater) in several lipid systems in which homogeneous mixingof lipid species is observed even on small distance scales (Ahmedet al., 1997; Wang and Silvius, 2001; T.-Y. Wang and J. R. Silvius,unpublished results). These systems include DOPC, DOPC/cholesterol,and DOPC/SOPC/cholesterol bilayers as well as cholesterol-freebilayers combining DOPC with DMPC, sphingomyelin, or SOPC abovetheir transition temperatures. By contrast, for mixtures ofthese lipids that have been shown to form micron-sized domainsby fluorescence microscopy (bilayers combining equimolar proportionsof cholesterol, DOPC, and either sphingomyelin or DMPC at temperatures $<=$ 25°C (Dietrich et al., 2001a; Veatch and Keller, 2002)),the present approach correctly indicates a marked inhomogeneityin lipid lateral organization. For systems for which comparisonscan be made with results obtained previously by other methods,the present approach thus appears to report faithfully the homo-or inhomogeneity of lipid organization (on a spatial scale oftens of nanometers or greater) within the bilayer. Importantly,in no case does the FRET approach give indications of an inhomogeneouslateral distribution of the lipids in systems whose componentsin fact mix homogeneously.

The major new finding provided by the present FRET experimentsis that lipid bilayers whose compositions approximate that ofthe outer leaflet of mammalian cell plasma membranes can exhibitdomain organization on a spatial scale similar to the inferreddimensions of lipid rafts (tens of nanometers or greater), evenat physiological temperatures and cholesterol contents wherelarge (micron-sized) segregated domains have not been observed.Fluorescence and atomic force microscopy have revealed segregationof fluid lipid domains under certain conditions in bilayerscombining cholesterol, high-melting phospho- or sphingolipids,and low-melting phospholipids (Dietrich et al., 2001a,b; Feigensonand Buboltz, 2001; Milhiet et al., 2001; Rinia and de Kruijff,2001; Rinia et al., 2001; Samsonov et al., 2001; Veatch andKeller, 2002, 2003). However, these studies have also reportedthat in bilayers with compositions (including cholesterol contents)that approximate those of the outer monolayer of mammalian cellplasma membranes, micron-sized domains typically disappear atphysiological temperatures (Dietrich et al., 2001a; Veatch andKeller, 2002, 2003). Fluorescence-quenching studies have indicatedthat on a distance scale approaching nearest-neighbor separations,inhomogeneity in lipid distributions can still be detected insuch systems at physiological temperatures (Ahmed et al., 1997;Wang et al., 2000; Wang and Silvius, 2003). It has not previouslybeen determined, however, whether the inhomogeneity detectedin these systems by the latter approach extends to spatial dimensionscomparable to those estimated for lipid rafts. The present dataindicate that this is in fact the case. At 37°C, for bilayerscombining saturated phospho- or sphingolipids with unsaturatedphospholipids and physiological proportions of cholesterol,the FRET assay gives strong indications of an inhomogeneouslateral organization (domain formation) on a spatial scale oftens of nanometers or greater. Since as already noted micron-sizeddomains have not been observed in such systems at 37°C,the segregated microenvironments detected by FRET in these systemswould appear to exhibit dimensions comparable to those inferredfor rafts in biological membranes, i.e., at least tens of nanometersbut considerably less than one micron in size (Varma and Mayor,1998; Pralle et al., 2000). The present results do not provideany information about the geometries of the domains formed inthese systems, which as noted elsewhere (Feigenson and Buboltz,2001) could for example exist as very elongated, ramifying structuresas small as a few tens of nanometers in width rather than ascompact, disc-shaped regions.

Feigenson and Buboltz (2001) have previously reported that forthe DPPC/dilauroyl PC (DLPC)/cholesterol ternary system at 22°C,inhomogeneities in lipid lateral distributions can be detectedby FRET at cholesterol contents up to $~$ 25 mol%, whereas domainsvisible by fluorescence microscopy disappear at somewhat lowercholesterol levels. This finding appears to agree with our observationthat for several of the lipid systems examined here, inhomogeneitiesin lipid distributions can be detected by FRET under conditions(temperatures $>=$ 30°C and/or high cholesterolcontents) where formation of micron-sized domains has not beenobserved (Dietrich et al., 2001a; Veatch and Keller, 2002, 2003).For several of the systems examined here, however, inhomogeneityin lateral organization can still be observed by FRET for cholesterolcontents ranging up to at least 50 mol%. These observationsare not necessarily in conflict with those reported for theDPPC/DLPC/cholesterol system. First, of course, the detailedphase behavior of the latter system may differ significantlyfrom that of the systems examined here. Second, and as Feigensonand Buboltz noted in their report, it is also possible thatnanoscopic domains exist in DPPC/DLPC/cholesterol bilayers atsterol contents well above 25 mol% but were not clearly detectedby the specific donor/acceptor probe combination used in thatstudy. The findings of this study can thus be considered toagree at least qualitatively with those reported by Feigensonand Buboltz. These authors have previously noted the potentialcorrelation between the "nanoscopic" segregation of differentlipid environments in cholesterol-containing lipid bilayersand the formation of lipid rafts with small dimensions in biologicalmembranes.

Like any probe-based methodology, the approach described heremay carry potential limitations. However, these limitationsare likely to result in failure to detect lateral inhomogeneityin lipid bilayers under certain circumstances, rather than toprovide erroneous indications for such inhomogeneity in systemswhere it is absent. In some types of bilayers the two donorspecies could prove to be too similar in their partitioningbetween different lipid domains, or the acceptor species mightnot discriminate sufficiently in its partitioning between differentdomains, to allow the presence of such domains to be detected.As already discussed, the present FRET method is not well suitedto detect inhomogeneities on scales of distances smaller than $~$ 10 nm. For such applications, fluorescence methods employingspin-labeled or brominated phospholipids are more appropriate(Silvius, 1992; Ahmed et al., 1997). A further, though lesser,caveat in the use of the present approach is that energy transferbetween donor and acceptor molecules in opposite leaflets ofthe bilayer may attenuate somewhat (though not eliminate) thesignature for inhomogeneity in bilayer organization in caseswhere the lateral organization of the two leaflets of the bilayeris uncorrelated. These latter effects are expected to be relativelymodest, however, based on the estimates of R_o for the probesused here (Fung and Stryer, 1978; Wolber and Hudson, 1979) andthe experimental findings of Connor and Schroit (1987) for closelyrelated fluorescent probes. Moreover, such effects will be furtherreduced in cases where lipid lateral organization is correlatedbetween the two halves of the bilayer, as has been observedin both cholesterol-containing and cholesterol-free systems(Korlach et al., 1999; Dietrich et al., 2001a).

The fluorescence-based approach utilized in this study differsfrom previously proposed FRET-based approaches, notably in itsuse of a matched pair of donor probes that bear four ratherthan two acyl chains to accentuate the differential partitioningof these species between different bilayer microenvironments.The fluorescence species employed here were designed specificallyto examine systems combining saturated and unsaturated lipidswith cholesterol, whose compositions resemble those of the outerleaflets of most mammalian cell plasma membranes (van Meer,1989). However, other types of lipid mixtures, such as mixturescombining cholesterol and monounsaturated phospholipids withhighly unsaturated phospholipids, have also been suggested toform microdomains of nanoscopic dimensions (Huster et al., 1998;Polozova and Litman, 2000; Brzustowicz et al., 2002). Combinationsof donor and acceptor probes related to those examined here,but bearing for example different acyl chains, may prove usefulto detect potential formation of microdomains in these lattersystems as well.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

This research was supported by an operating grant from the CanadianInstitutes of Health Research (MOP-7776) to J.R.S.

Submitted on March 19, 2003; accepted for publication May 7, 2003.

REFERENCES

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