The Effect of Ergosterol on Dipalmitoylphosphatidylcholine Bilayers: A Deuterium NMR and Calorimetric Study

doi:10.1529/biophysj.104.051375

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

The Effect of Ergosterol on Dipalmitoylphosphatidylcholine Bilayers: A Deuterium NMR and Calorimetric Study

Ya-Wei Hsueh^*, Kyle Gilbert^*, C. Trandum, M. Zuckermann^* and Jenifer Thewalt^*

^* Department of Physics, and Department of Molecular Biology and Biochemistry, Simon Fraser University, Burnaby, British Columbia, Canada, V5A 1S6; MEMPHYS-Center for Biomembrane Physics, University of Southern Denmark, DK-5230 Odense, Denmark; and Department of Chemistry, Roskilde University Center, 4000 Roskilde, Denmark

Correspondence: Address reprint requests to Dr. Jenifer Thewalt, Fax: 604-291-3592; E-mail: jthewalt{at}sfu.ca.

ABSTRACT

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

We have studied the effect of ergosterol, an important componentof fungal plasma membranes, on the physical properties of dipalmitoylphosphatidylcholine(DPPC) multibilayers using deuterium nuclear magnetic resonance(²H NMR) and differential scanning calorimetry (DSC). For the²H NMR experiments the sn-1 chain of DPPC was perdeuteratedand NMR spectra were taken as a function of temperature andergosterol concentration. The phase diagram, constructed fromthe NMR spectra and the DSC thermograms, exhibits both solid-ordered(so) + liquid-ordered (lo) and liquid-disordered (ld) + lo phasecoexistence regions with a clear three-phase line. This is thefirst demonstration that lo domains exist in liquid crystallinemembranes containing ergosterol. The domain sizes in the ld+lophase coexistence region were estimated by analyzing the exchangeof labeled DPPC between the two regions, and depend on ergosterolconcentration. The DPPC-ergosterol phase diagram is similarto that of the DPPC-cholesterol multibilayer system except thatthe so+lo and ld+lo phase coexistence regions are considerablybroader.

INTRODUCTION

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

Sterols are essential components of eukaryotic cells both asstructural membrane components and as initiators and regulatorsof biological processes. In particular, cholesterol is ubiquitousin mammalian cells and ergosterol is the major sterol in certainfungi and protozoans, where it fulfills several important functions.In the unicellular eukaryote, Saccharomyces cerevisiae, Rodriguezet al. (1985) have identified four of these functions, whichinclude growth (sparking) and bulk requirements, the latterrelated to maintaining membrane integrity under physiologicalconditions. Recently Kuebler et al. (1996) found evidence forthe presence of Triton X-100 insoluble fractions in S. cerevisiaeplasma membrane lipids, which implied the existence of "rafts"in the plasma membrane. Bagnat et al. (2000) showed that themajor components of rafts in the plasma membrane of S. cerevisiaeare phosphoinositol-based sphingolipids and ergosterol. Thesame authors found that, in contrast to mammalian rafts, theassembly of rafts in S. cerevisiae starts in the endoplasmicreticulum (ER) and that glycophosphatidylinositol anchored proteinsassociate with rafts in the ER. Bagnat et al. (2001) found thatthe major yeast plasma membrane protein, plasma membrane ATPase(Pma1p), needs to be associated with rafts for delivery to theplasma membrane. In vitro studies by Xu et al. (2001) usingternary lipid mixtures containing ergosterol support the presenceof rafts in yeast.

The lipid composition of the S. cerevisiae plasma membrane hasbeen studied extensively (Longley et al., 1968; Bottema et al.,1985; Patton and Lester, 1991, Zinser et al., 1991, 1993; Tulleret al., 1999). Until recently, however, most investigationsreported on the fatty acid and polar head moieties of the lipidmolecules and the detailed composition of individual lipid moleculeswas not known. Schneiter et al. (1999) identified the specificlipid molecules of both the plasma membrane and the membranesof the organelles of the X2180-1F wild-type strain of S. cerevisiaeusing electrospray ionization tandem mass spectrometry. Theresults for the plasma membrane are as follows. Phosphoinositol-basedsphingolipids form 30% of the total phospholipid content ofthe plasma membrane, the other 70% being composed of glycerophospholipids(GPLs) in agreement with the results of Patton and Lester (1991).Interestingly, the amide-linked chain of the sphingolipids ishighly saturated and unusually long (C26:0) and free ceramidewith the same chain length is also present in abundance. (Itis not known, however, whether the ceramide is present as aprecursor of the sphingolipids or whether it has a specificfunction in the plasma membrane.) In this context, the resultsof Eisenkolb et al. (2002) indicate that the (26:0) chains ofthe sphingolipids are vital for the establishment of raft associationby Pma1p and the stability of this protein at the cell surfaceof yeast. These authors also established that the presence ofergosterol rather than cholesterol is a structural requirementfor this association. The S. cerevisiae plasma membrane GPLsare chiefly composed of a saturated acyl chain (e.g., C16:0or C18:0) and a monounsaturated acyl chain (e.g., C16:1). Incontrast to the case of higher eukaryotic cells neither glycolipidsnor GPLs with polyunsaturated acyl chains were found.

The range of polar heads of the GPLs had already been analyzedby Zinser et al. (1991, 1993) for the same strain of S. cerevisiaein the same growth medium. The major GPL species were foundto be phosphatidylcholine (PC), phosphatidylinositol, phosphatidylserine,and phosphatidylethanolamine. The concentration of ergosterolin the S. cerevisiae plasma membrane has been somewhat controversial.For example, Patton and Lester (1991) reported a 1:1 molar ratioof ergosterol/phospholipid whereas Zinser at al. (1991, 1993)found an ergosterol/phospholipid ratio of 3.5:1. More recently,Schneiter et al. (1999) found an ergosterol/phospholipid ratioof 0.46:1, which is, as they point out, comparable to the cholesterol/phospholipidratio of 0.35:0.53 obtained for higher eukaryotic cells.

Here we study the properties and phase behavior of multilamellardispersions of dipalmitoylphosphatidylcholine (DPPC) and ergosterol.Saturated PCs are known to have very similar physical chemicalbehavior to that of saturated-chain sphingomyelins (Ohvo-Rekiläet al., 2002). Furthermore, sphingolipids with deuterated acylchains are not available commercially at present. Therefore,because the presence of rafts in yeast membranes is conjecturedto result from the interaction between ergosterol and lipidmolecules with high melting temperatures, DPPC-ergosterol isa good model in which to study phase behavior in a comprehensiveway. In this context, it is usually assumed that rafts are ina tightly packed liquid-ordered (lo) phase where the sterolsorder the chains of the high melting lipids but the rafts retaintheir lateral fluidity. It is of interest to note that Xu etal. (2001) have found that ergosterol promotes the formationof raft-like domains more strongly than cholesterol. IndeedUrbina et al. (1995) have shown that 30 mol% ergosterol ordersthe acyl chains of dimyristoylphosphatidylcholine (DMPC) morestrongly than cholesterol. Endress et al. (2002) compare theeffect of cholesterol and ergosterol on the mechanical propertiesof DPPC bilayers. These authors find that the area compressibilitymodulus of DPPC bilayers containing 40 mol% ergosterol at 10°Cis a factor of 1.5 higher than in the case of cholesterol. Thisfits well with the ²H NMR results of Urbina et al. (1995) forDMPC-sterol multibilayers.

The experimental methods used here to study DPPC-ergosterolmembranes are ²H NMR spectroscopy and DSC. Aqueous multilamellardispersions (MLDs) of ergosterol and sn-1 chain perdeuteratedDPPC were used to obtain the chain order parameter as a functionof temperature, T, and ergosterol mol fraction, x. Analysisbased on and extended from that of Vist and Davis (1990) wasapplied to both the ²H NMR spectra and the DSC thermograms todetermine the T-x phase diagram. The phases making up this phasediagram are the same as those found by Vist and Davis (1990)and the notation due to Ipsen et al. (1987) is used to characterizethem in this study. The gel phase of pure phospholipid bilayersis referred to as the solid-ordered (so) phase, the liquid crystallinephase of pure lipid bilayers is referred to as the liquid-disordered(ld) phase, and the ß-phase of Vist and Davis (1990),which is found at higher cholesterol concentrations, is referredto as the liquid-ordered (lo) phase. The terms solid and liquidare used to characterize the nature of the phase whereas thewords ordered and disordered indicate the conformational natureof the lipid acyl chains.

MATERIALS AND METHODS

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

DPPC-d31 and DPPC were obtained from Avanti Polar Lipids (Alabaster,AL). Ergosterol and cholesterol were obtained from Sigma-AldrichCanada (Oakville, ON). Deuterium-depleted water was from Sigma-AldrichCanada.

²H NMR spectroscopy
DPPC-d31/ergosterol multilamellar dispersions were preparedfor ergosterol concentrations of 0, 5, 10, 13, 16, 20, 25, 27.5,30, 35, and 42 mol%. DPPC-d31 and ergosterol were mixed in theappropriate quantities, dissolved in benzene/methanol, 4:1 (v/v),and then freeze-dried. Samples were hydrated using a pH 7.4buffer prepared in deuterium-depleted water containing 50 mMHEPES, 150 mM NaCl, 4 mM EDTA. Hydration was performed by freeze-thaw-vortexcycling five times between liquid nitrogen temperature and 50°C.²H NMR experiments were performed on a locally built spectrometerat 46.8 MHz using the quadrupolar echo technique (Davis et al.,1976). The typical spectrum resulted from 10,000–15,000repetitions of the two-pulse sequence with 90° pulse lengthsof 3.95 µs, interpulse spacing of 40 µs, and dwelltime 2 µs. The delay between acquisitions was 300 ms anddata were collected in quadrature with Cyclops eight-cycle phasecycling. The spectra were depaked using the procedure describedby Lafleur et al. (1989). The spin-spin relaxation time, T_2e,was measured by varying the interpulse spacing from 40 to 100µs and taking the initial slope of the echo peak signalversus echo time. The sample was heated from 15 to 60°C.At each temperature, the sample was allowed to equilibrate for20 min before a measurement. The first moment, M₁, was calculatedusing

where ${omega}$ is the frequency shift fromthe central (Larmor) frequency, f( ${omega}$ ) is the spectral intensity,and .

The boundaries of the so+lo coexistence region are determinedby the spectral subtraction method (Vist and Davis, 1990; Thewaltand Bloom, 1992). Within the two-phase region, the ²H NMR spectrumS is a superposition of the weighted so and lo spectra:

(1)

(2)
where x_A and x_B arethe ergosterol concentrations of two DPPC-d31/ergosterol MLDs,x_s and x_f are the ergosterol concentrations at the so and lophase boundary, f_A and f_B are the fractions of lo phospholipidin the two samples, and S_s and S_f are the end-point spectracharacteristic of so- and lo-phase domains, respectively, atthe so and lo phase boundaries. Given two area-normalized ²HNMR spectra and the so (or lo) spectrum can be obtained by subtracting a fractionK (or K') of one spectrum from the other. K is the ratio oflo-phase phospholipid fractions in the two samples, f_A/f_B, andK' is the ratio of so phase phospholipid fractions in the twosamples (1 – f_B)/(1 – f_A). Using the K and K' valuesdetermined from the spectral subtraction, the phase boundaries,x_s and x_f, can then be calculated:

(3)

(4)

The spectral subtraction method is valid as long as certainassumptions hold. The spectra of the two phases, S_s and S_f,have to be sufficiently different that one can easily distinguishand carry out the subtraction procedure. The exchange of labeledlipid between two kinds of domains must be slow on the NMR timescaleso that it can be neglected. In addition, the domain must besufficiently large, so that the signal from the lipid on theboundary of the domains is negligible. Also, this method assumesthat both phases have the same relaxation time T_2e, which isnot true in this case. We found that the lo phase has a T_2eone to six times larger than the so phase T_2e (depending onthe temperature), hence the so component decays with time fasterthan the lo component (). Thus, at any given quadrupolar echo time 2 ${tau}$ , the ²H NMR spectrum will contain asmaller so component S_s than is representative of the sample.f_A and f_B in Eqs. 1 and 2, which should be denoted as f_A(t =2 ${tau}$ ) and f_B(t = 2 ${tau}$ ), do not reflect the actual fraction of fluidphospholipid in the samples due to this T_2e effect. Thus, theK and K' (which should be denoted as K(t = 2 ${tau}$ ) and K'(t = 2 ${tau}$ ),respectively) determined from the spectral subtraction willnot be correct, leading to a deviation of x_s and x_f from theactual values. To eliminate this T_2e effect, corrected f_A andf_B values (i.e., f_A(t = 0) and f_B(t = 0)) are calculated byextrapolating the height of the respective echo signal backto t = 0 using the measured T_2e for a given temperature, andthen the corrected K and K' values (i.e., K(t = 0) and K'(t= 0)) can be derived and expressed in terms of the experimentallydetermined K, K' (i.e., K(t = 2 ${tau}$ ), K'(t = 2 ${tau}$ )), and T_2es. UsingEqs. 3 and 4 with these corrected K and K' values, the T_2e-correctedvalues of x_s and x_f are obtained.

Differential scanning calorimetry
DSC measurements were performed on DPPC/ergosterol MLDs at ergosterolconcentration of 0, 5, 10, 13, 20, 25, 30, and 40 mol%. Suspensionsof multilamellar liposomes (5 mM) were prepared. After weighing,the dry lipids were cosolubilized in a chloroform/methanol 2:1mixture (or hydrated immediately in the case of pure DPPC).Chloroform/methanol was driven off by a stream of nitrogen,and the samples were stored under low pressure for at least72 h. The resulting dry lipid films were then dispersed in purewater. The temperature was kept at 60°C for 1 h during whichthe suspensions were shaken vigorously several times. The DSCscans were made using a DSC Nanocal (Calorimetry Science, Provo,UT). No baseline correction was applied to the data.

RESULTS AND DISCUSSION

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

²H NMR spectra were collected from 15 to 60°C. Fig. 1 Ashows that pure DPPC-d31 MLDs undergo a gel (so) to liquid-disordered(ld) phase transition near 40°C (T_m) as the temperatureis raised. The spectra obtained above 41°C display pureld phases. The spectrum is a superposition of Pake doublets,indicating that the membrane is in the ld phase where the acylchain undergoes rapid, axially symmetric reorientation aboutthe bilayer normal. The spectra obtained below 39°C arecharacteristic of a pure so phase membrane. Deuterons in somembranes do not undergo axially symmetric motion on the NMRtimescale because the acyl chains are closely packed. The spectrumobtained at 40°C is composed of both so and ld components.The spectrum of the 95:5 DPPC-d31/ergosterol MLD at 40°Calso displays both so and ld components (Fig. 1 B), but withthe ld component dominating. The residual gel component canbe observed by magnifying the tail of the spectrum, which extendsbeyond 50 kHz (see arrow in Fig. 1 B). This indicates that theso to ld transition occurs at a lower temperature in the presenceof 5 mol% ergosterol.

View larger version (22K):
[in this window]
[in a new window]

FIGURE 1 ²H NMR spectra of (A) pure DPPC-d31 and (B) 95:5 DPPC-d31/ergosterol as a function of temperature.

Adding ergosterol affects DPPC-d31 membranes in both the ldand so states. Fig. 2 shows the spectrum of DPPC-d31/ergosteroldispersions at 42°C (i.e., above T_m) as a function of ergosterolconcentration. DPPC-d31 MLDs with up to 5 mol% ergosterol displaypure ld phase spectra. With increasing ergosterol concentrationthe average spectral width increases and the individual peaksbroaden. At 27.5 mol% ergosterol, the individual peaks becomesharper and remain sharp at higher ergosterol concentration.These spectra are the typical pure lo phase spectra: a superpositionof Pake doublets having an average spectral width (e.g., 107,000s^–1 for 27.5 mol% ergosterol) nearly twice that of theld phase (e.g., 56,000 s^–1 for pure DPPC-d31) due to thehighly conformationally ordered lipid chains. For ergosterolconcentrations between 10 and 25 mol%, the broadening of theindividual doublets in the spectrum suggests an ld+lo phasecoexistence. Therefore, ergosterol induces lo-phase domainsin DPPC-d31 bilayers.

View larger version (19K):
[in this window]
[in a new window]

FIGURE 2 ²H NMR spectra of DPPC-d31/ergosterol as a function of ergosterol concentration at T = 42°C.

Fig. 3 shows the spectrum of DPPC-d31/ergosterol as a functionof ergosterol concentration at 38°C (i.e., below T_m). The0 mol% ergosterol and 5 mol% ergosterol samples display so phasespectra. For the 10 mol% ergosterol sample, a small lo componentappears in addition to the so spectrum, as indicated by theemergence of "peaks" near ±15 and ±20 kHz. Thecoexistence of so and lo phases indicates that ergosterol induceslo domains in the DPPC-d31 bilayers. The proportion of lo componentincreases as the ergosterol concentration increases (see spectraat 13, 16, and 20 mol%). Concurrently, the proportion of socomponent decreases. Therefore, adding ergosterol decreasesthe propensity of DPPC-d31 membranes to form the so phase. Asthe ergosterol concentration reaches 25 mol% and higher, theDPPC-d31 membranes are entirely in the lo phase and exhibitlo phase spectra.

View larger version (19K):
[in this window]
[in a new window]

FIGURE 3 ²H NMR spectra of DPPC-d31/ergosterol as a function of ergosterol concentration at T = 38°C.

The spectra as a function of temperature for 84:16 DPPC-d31/ergosterolare shown in Fig. 4. The spectra of 26, 30, 34, and 38°Cshow that there is so+lo phase coexistence in the DPPC/ergosterolmembrane. At 26°C, the spectrum consists mostly of the socomponent with a very small amount of the lo component as indicatedby the emergence of Pake doublet peaks within the central partof the spectrum (±20 kHz). These Pake doublet peaks becomemore prominent as temperature increases and the so componentis reduced. At 38°C, the lo component dominates the spectrum.At 42, 46, and 50°C, lo+ld phase coexistence is observed.This is found by examining the individual peaks of the depakedspectra. These peaks are broadened, indicating the coexistenceof ld and lo components (see discussion of Fig. 7 below). At55 and 60°C, a pure liquid crystalline phase is observed,where the individual peaks of the depaked spectra become sharp.

View larger version (18K):
[in this window]
[in a new window]

FIGURE 4 ²H NMR spectra as a function of temperature for 84:16 DPPC-d31/ergosterol.

View larger version (24K):
[in this window]
[in a new window]

FIGURE 7 The depaked spectra of 75:25 DPPC-d31/ergosterol as a function of temperature. Because the spectra are symmetrical, we show only the high-frequency half of each.

The first moment, M₁, measures the average spectral width. Eachphase state has a distinct ²H NMR spectrum and thus a distinctM₁ value. A large variation of M₁ with temperature can be usedto pinpoint phase transition temperatures in the membrane. Fig. 5shows M₁ as a function of temperature for all DPPC-d31/ergosterolMLDs. Pure DPPC-d31 undergoes a pretransition at 31°C fromthe L_ß' phase to the P_ß' phase and a maintransition at 40°C from the P_ß' phase to the Lphase as the temperature is raised. Note that the L_ß'phase and the P_ß' phase are so phases and the L phaseis synonymous with the ld phase. The M₁(T) curve plunges lessdramatically at T_m as more ergosterol is added: below T_m M₁(T)decreases with increasing ergosterol concentration, whereasabove T_m M₁(T) increases with increasing ergosterol concentration.M₁ is proportional to the average order parameter in the liquidcrystalline phase. Therefore, adding ergosterol increases theDPPC-d31 chain ordering above T_m. The so to ld transition forDPPC-d31/ergosterol MLDs containing 10–20 mol% ergosteroloccurs at a constant temperature, T_m = 39.5 ± 0.5°C,implying the existence of a three-phase line in the phase diagram.For DPPC-d31/ergosterol MLDs containing ergosterol concentrationsof 25 mol% and above, the so to ld phase transition is absent.

View larger version (23K):
[in this window]
[in a new window]

FIGURE 5 The temperature dependence of M₁ for DPPC-d31/ergosterol at various ergosterol concentrations: 0 mol% ( ${blacktriangledown}$ ); 5 mol% ( ${triangleup}$ ); 10 mol% ( ${blacksquare}$ ); 13 mol% ( ${circ}$ ); 16 mol% ( ${diamondsuit}$ ); 20 mol% ( ${nabla}$ ); 25 mol% (•); 27.5 mol% ( ${diamond}$ ); 30 mol% ( ${blacktriangleup}$ ); 35 mol% ( ${square}$ ); 42 mol% ( ${oplus}$ ).

To further explore the phase behavior of DPPC-d31/ergosterolMLDs in the liquid crystalline phase, we have plotted M₁ asa function of ergosterol concentration at various temperaturesabove T_m (Fig. 6). Because M₁ is proportional to the averageorder parameter, each curve in Fig. 6 displays the progressionof the average order parameter with increasing ergosterol concentrationat a given temperature. The average order parameter of MLDscontaining coexisting lo and ld phases is expected to be mostsensitive to increasing ergosterol concentration because a proportionof ld phase will be converted to the much more ordered lo phaseupon ergosterol addition. For lo-phase MLDs the effect of addedergosterol will be more modest. The M₁(ergosterol) curves, exceptat 57°C, exhibit two distinct ergosterol concentration-dependentbehaviors: below 27.5 mol% ergosterol the average order parameterincreases rapidly as ergosterol concentration increases, whereasabove 27.5 mol% ergosterol the average order parameter increasesslowly or levels off as ergosterol concentration increases.The NMR spectra suggest that at these temperatures the 75:25DPPC-d31/ergosterol MLD has coexisting ld+lo phases whereasthe 70:30 DPPC-d31/ergosterol MLD is in the lo phase. Therefore,the changes of slope in the M₁(ergosterol) curve suggests ald+lo/lo boundary near 27.5 mol% ergosterol. To determine thisboundary, we drew a line through the points for 20 and 25 mol%ergosterol (or 25 and 27.5 mol%) and fitted another line tothe points between 27 and 42 mol% ergosterol (or 30 and 42 mol%).The ld+lo/lo boundary is then obtained from the intercept ofthe two lines. In principle there should be a similar changein slope at low ergosterol concentrations, reflecting crossingthe ld/ld+lo phase boundary. However, these slope changes areless obvious than those at the ld+lo/lo boundary. Thus, theld/ld+lo phase boundary has instead been determined by directexamination of the spectra (see discussion of Fig. 8).

View larger version (28K):
[in this window]
[in a new window]

FIGURE 6 M₁ as a function of ergosterol concentration for DPPC-d31/ergosterol at: 41°C (•); 42°C ( ${diamond}$ ); 43°C ( ${blacksquare}$ ); 44°C ( ${otimes}$ ); 45°C ( ${blacktriangleup}$ ); 47°C ( ${circ}$ ); 48°C ( ${blacktriangledown}$ ); 49°C ( ${square}$ ); 50°C ( ${diamondsuit}$ ); 53°C ( ${triangleup}$ ); 57°C ( ${oplus}$ ). The lines are guides to the eye.

View larger version (23K):
[in this window]
[in a new window]

FIGURE 8 The depaked spectra of DPPC-d31/ergosterol as a function of ergosterol concentration at T = 45°C.

The T = 41°C curve in Fig. 6 levels off at an ergosterolconcentration of $~$ 27.5 mol%, implying that at 41°C the labeledDPPC chain has reached its maximum sterol-enhanced order. Asnoted above, the T = 57°C curve behaves differently fromthe others; in particular the value of M₁ increases steadilywith increasing ergosterol concentration all the way to 42 mol%ergosterol, implying no crossing of the phase boundary.

Another approach to determining the ld+lo/lo boundary is byexamining the temperature-dependent variation in width of individualPake doublet peaks. This is best done using depaked spectra.Fig. 7 shows the depaked spectra of 25 mol% ergosterol from37°C, where the membrane is in the lo phase, to 60°C,where the membrane is in the ld phase. There is a slow decreasein the quadrupolar splittings from T = 37–41°C. Theindividual peaks in the spectrum remain sharp. Above 41°C,the individual peaks broaden significantly and the quadrupolarsplittings decrease faster as a function of temperature, indicatingmembrane heterogeneity in the form of ld+lo phase coexistence.Lipids diffusing between ld and lo domains with a rate fasterthan the NMR timescale will yield spectra having broadened individualpeaks. As this MLD is heated, a phase boundary reflecting theonset of ld+lo phase coexistence occurs around 41°C. Thebroad individual peaks persist at higher temperatures untilat 53°C the individual peaks become narrow again, implyingthat the membrane no longer displays ld+lo phase coexistence.The individual peaks remain narrow at higher temperatures andthe rate of decrease in the quadrupolar splittings as a functionof temperature slows down. Thus, a second phase boundary (fromld+lo to a single liquid crystalline phase) occurs around 53°C.Similar analysis of the 72.5:27.5 DPPC-d31/ergosterol MLD'sspectra yielded phase boundaries for the ld+lo coexistence regionat 43 and 50°C.

More insight into the ld+lo phase coexistence region is gainedby examining the depaked spectra as a function of ergosterolconcentration at a temperature above T_m. An example of the variationsin spectral width and sharpness of individual peaks at 45°Cis given in Fig. 8. At low ergosterol concentrations ( $≤$ 10 mol%)the spectral lines are sharp. They blur from 13 to 27.5 mol%ergosterol (and the spectral width also increases rapidly forthis concentration range) and are sharp again at ergosterolconcentrations $≥$ 30 mol%. These "blurry" spectra are further analyzedbelow. Thus, the ld/ld+lo phase boundary lies between 10 and13 mol% ergosterol and the ld+lo/lo phase boundary between 27.5and 30 mol% ergosterol.

Fig. 9 shows the DSC scans of DPPC/ergosterol membranes. PureDPPC displays a sharp main transition (so to ld transition)near 41.5°C. At 5 mol% ergosterol, the main transition becomesbroadened and shifts toward lower temperature. The DSC behaviorof the 0 and 5 mol% ergosterol MLDs are consistent with theNMR data discussed in the previous paragraph. The broad transitionin the 5 mol% ergosterol membrane indicates a so and ld phasecoexistence region. As ergosterol concentration increases from10 to 20 mol%, the intensity of the main peak decreases, butthe peak position seems to remain unchanged. A broad shoulderappears on the high-temperature side of the sharp peak, suggestinga two-phase region. We obtained the ld+lo/ld phase boundaryby finding the temperatures where the broad peak ends (Vistand Davis, 1990). At concentrations of ergosterol at 30 mol%and above a very broad residual endotherm is observed, similarto that seen in DPPC/cholesterol MLDs.

View larger version (18K):
[in this window]
[in a new window]

FIGURE 9 DSC scans of DPPC/ergosterol. Note that to compare DSC with NMR data one must shift the DSC temperature by –2°C, given the fact that DPPC chain deuteration reduces the transition temperature by 2°C.

The partial phase diagram for DPPC-d31/ergosterol determinedfrom the characteristic phase transition temperatures and thecorresponding lipid compositions as discussed above is shownin Fig. 10. The ld/ld+lo boundary (open diamonds), determinedfrom the spectral changes described in Fig. 8 is consistentwith that obtained from the DSC data (solid diamonds). The ld+lo/loboundary in Fig. 10 is determined from the changes of slopein the M₁ versus ergosterol concentration curves (Fig. 6), aswell as by examining the temperature-dependent changes in thedepaked spectra of 25 and 27.5 mol% ergosterol as discussedearlier (Fig. 7). These two sets of data are quite consistentand agree with the boundary obtained by examining the changesin the ergosterol-dependent depaked spectra discussed in Fig. 8.The boundaries of the so+lo phase coexistence region (solidsquares) are obtained using the well-established spectral subtractionmethod, described in detail in Materials and Methods. The opentriangles, obtained from the onset of the transition in theM₁(T) curves MLDs having high ergosterol concentrations in Fig. 5,define the so+lo/lo boundary, consistent with the data obtainedfrom spectral subtraction.

View larger version (15K):
[in this window]
[in a new window]

FIGURE 10 Partial phase diagram of the DPPC/ergosterol membrane. Midpoint of the transition from M₁(T) curves (Fig. 5) (•); onset or end of transition in M₁(T) curves ( ${square}$ ); obtained by inspection of the depaked spectra versus ergosterol concentration (Fig. 8) ( ${diamond}$ ); end of transition in DSC data (shifted by –2°C) ( ${diamondsuit}$ ); obtained by inspection of the depaked spectra versus temperature (Fig. 7) ( ${blacktriangleup}$ ); obtained from M₁(ergosterol) curves (Fig. 6) ( ${circ}$ ); obtained from spectral subtraction ( ${blacksquare}$ ); the onset of transition in M₁(T) curves for MLDs having ergosterol concentrations of 25, 27.5, or 30 mol% ( ${triangleup}$ ).

We have identified three two-phase regions and a three-phaseline in the DPPC/ergosterol partial phase diagram, as shownin Fig. 10. There is a so+ld phase coexistence region at $~$ 40°Cbetween 0 and $~$ 9 mol% ergosterol. There is a so+lo phase coexistenceregion below 39.5°C between $~$ 9 mol% ergosterol and 25–32mol% ergosterol and a ld+lo phase coexistence region above 39.5°Cbetween 10–15 mol% ergosterol and 25–28 mol% ergosterol.The upper bound of the ld+lo phase coexistence region lies inthe neighborhood of 53°C, consistent with the discussionregarding Fig. 6. The boundary separating the so+lo and ld+loregions is a so+ld+lo three-phase coexistence line at 39.5°C.

We compare the partial phase diagram of DPPC-d31/ergosterolwith that of DPPC-d62/cholesterol by Vist and Davis (1990).Both diagrams contain a three-phase line and three two-phaseregions. (Note that Huang et al., 1993 used ¹³C-NMR and DSCdata to construct a similar phase diagram for PC-cholesterolbut with a different interpretation for the phase behavior interms of microdomain formation and continuous phase transitions.)The so/so+lo boundary lies close to 9 mol% for DPPC-d31/ergosteroland around 7 mol% for DPPC-d62/cholesterol, which are consistentwithin error. However, the so+lo/lo boundaries are quite different.The so+lo/lo boundary of DPPC-d62/cholesterol occurs around22.5 mol% and is nearly vertical. The boundary of the so+lo/lotwo-phase region characterizes the composition of lo domainswithin the two-phase region. A nearly vertical boundary indicatesthat the composition of lo domains depends only slightly ontemperature. On the other hand, because the so+lo/lo boundaryof DPPC-d31/ergosterol slopes from 25 mol% near T_m toward 32mol% at 27°C, the composition of lo domains depends stronglyon temperature. The ergosterol concentration required to formlo-phase domains in the DPPC-d31/ergosterol membrane is greaterthan the cholesterol concentration required to form lo-phasedomains in the DPPC-d62/cholesterol membrane, i.e., more ergosterolthan cholesterol is needed to obtain the lo phase. Thus, permolecule, ergosterol is less effective than cholesterol in promotingthe lo phase in so-phase DPPC bilayers.

The ld+lo phase coexistence region in DPPC/ergosterol is largerthan that in DPPC/cholesterol. The ld+lo/lo boundary of DPPC/ergosterolis located around 27.5 mol%, whereas that of DPPC/cholesterollies around 22.5 mol%, implying that more ergosterol than cholesterolis needed to obtain lo-phase domains in the ld-phase DPPC bilayers.Thus ergosterol is less effective than cholesterol in promotingthe lo phase in the ld-phase DPPC bilayers. Our observationof spectral line broadening in the ld+lo phase coexistence regionof DPPC-d31/ergosterol (Fig. 8) indicates that the diffusinglabeled lipids sample a heterogeneous membrane on the ²H NMRtimescale ( ${tau}$ ${cong}$ 10 µs). Taking the translational diffusioncoefficient to be $~$ 10^–11 m²/s (based on measurements inDMPC/cholesterol by Filippov et al., 2003) the root mean squareddisplacement of the DPPC, calculated from

(5)
inthis time is 20 nm. This rough estimate implies nanoscale separationbetween sterol-rich and sterol-poor regions, as was proposedfor cell membranes by Varma and Mayor (1998). Such small lengthscales are consistent with the lack of observation of micron-sizedphase-separated domains in binary phospholipid/cholesterol giantunilamellar vesicles (Veatch and Keller, 2003).

We now estimate the size of the domains involved in this ld+lonanoscale phase coexistence by applying the method commonlyused to understand A ${leftrightarrow}$ B chemical exchange, replacing chemicalshifts by quadrupole splittings. The lipid exchange time is

(6)
where k_–1 is the rate constant characterizinglipid exchange between lo and ld domains (k_–1 is assumedto be equal to k). This rate constant is obtained from

(7)
(Carrington and McLachlan, 1967), where f_A andf_B are fractions of spins in the lo and ld domains, respectively, ${Delta}$ ${delta}$ _AB = ${Delta}$ ${delta}$ _A – ${Delta}$ ${delta}$ _B is the difference of the quadrupolar splittingsin the two states, and T_{2, obs}, T_2A, and T_2B can be obtainedfrom the linewidths ${Delta}$ ${nu}$ of individual peaks (1/T₂ = ${pi}$ ${Delta}$ ${nu}$ ). We chosethe C15 peaks for this calculation because they are well resolved.Thus,

(8)
where ${Delta}$ ${nu}$ _{Q, lo} and ${Delta}$ ${nu}$ _{Q, ld} are thequadrupole splittings of the C15 doublets for the pure lo (30mol% ergosterol) and pure ld (10 mol% ergosterol) spectra, respectively.For T = 45°C, ${Delta}$ ${delta}$ _AB = 26,730 – 13,920 = 12,810 Hz. Therate constants T_{2, obs}, T_2A, and T_2B are calculated below:

(9a)

(9b)

(9c)
where ${Delta}$ ${nu}$ _lo+ld, ${Delta}$ ${nu}$ _lo, and ${Delta}$ ${nu}$ _ld are the widths at halfmaximum height of the individual C15 peaks in the depaked lo+ldspectra (13, 16, 20, and 25 mol% ergosterol), pure lo spectrum(30mol% ergosterol), and pure ld spectrum (10 mol% ergosterol),respectively. Thus, for T = 45°C

(10a)

(10b)
and Table 1 lists the results of these calculationsfor lo+ld membranes.

View this table:
[in this window]
[in a new window]

TABLE 1 A list of ${Delta}$ ${nu}$ _lo+ld, f_A, f_B values and calculated results ${tau}$ , ( $<$ ${Delta}$ x² $>$ )^1/2

The root mean squared distance ( $<$ ${Delta}$ x² $>$ )^1/2 traveled by DPPC-d31before it senses lo/ld heterogeneity is plotted as a functionof ergosterol concentration in Fig. 11. It is roughly U-shaped,which is reasonable given the likelihood of fewer lo/ld interfacesbeing found for membrane compositions near the boundaries ofthe lo+ld coexistence region of the phase diagram. Note thatif a more detailed estimate of the mean lateral diffusion coefficienthad been used in the final calculation of ( $<$ ${Delta}$ x² $>$ )^1/2 the fact thatthe diffusion constant in the ld phase is greater than the diffusionconstant in the lo phase would result in a larger root meansquared displacement for lower ergosterol concentrations anda more symmetric U-shape. The length scale characterizing thedomains is estimated to be twice ( $<$ ${Delta}$ x² $>$ )^1/2, i.e., 30–80nm, depending on sterol content. We have no information on domainshape, however, and because a highly convoluted domain is possibleif the energy associated with interfacial lipids is negligible,we cannot estimate the number of lipids constituting a domain.Interestingly, Veatch et al. (2004)

estimated domain sizes of $~$ 80 nm in dioleoylphosphatidylcholine/DPPC (1:1) + 30 mol% cholesterolmembranes displaying liquid/liquid coexistence at 25°C.

View larger version (12K):
[in this window]
[in a new window]

FIGURE 11 The root mean squared distance ( $<$ ${Delta}$ x² $>$ )^1/2 diffused by DPPC-d31 as a function of ergosterol concentration at T = 45°C. The lines are guides to the eye.

We now compare the effect of ergosterol and cholesterol on theacyl chain order parameter of liquid phase DPPC. This was accomplishedby measuring the CD₃ (C16) splitting of DPPC-d31/ergosteroland DPPC-d62/cholesterol. Fig. 12 shows that below 13 mol% sterol,where the membranes are in the ld phase, there is no differencein the ordering of the two DPPC/sterol membranes. This is consistentwith the simulation results of Smondyrev and Berkowitz (2001)

at 11 mol % sterol. On the other hand, at sterol concentrations>13 mol%, the C16 splitting of DPPC-d31/ergosterol is greaterthan that of DPPC-d62/cholesterol. This indicates that the chainordering of ergosterol-containing membranes is larger than thatof cholesterol-containing membranes; the ergosterol structureinhibits DPPC chain conformational freedom even more than doescholesterol. Therefore, in the ld+lo phase coexistence and thelo phase states, ergosterol orders DPPC chains more effectivelythan cholesterol. This result is consistent with the findingsof Urbina et al. (1995)

using 70:30 DMPC/sterol.

View larger version (13K):
[in this window]
[in a new window]

FIGURE 12 The quadrupolar splitting of the CD₃ doublet as a function of sterol concentration. DPPC-d31/ergosterol at 42°C ( ${blacksquare}$ ); DPPC-d62/cholesterol at 40°C ( ${square}$ ). The lines are guides to the eye.

	CONCLUSIONS

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

Similar to cholesterol, adding ergosterol to DPPC increasesthe average lipid chain order in the liquid crystalline phaseand interferes with the membrane's ability to form the so (orgel) phase below T_m. In the ld phase, ergosterol is no moreeffective than cholesterol in ordering DPPC chains. In regionsof ld+lo phase coexistence and in the lo phase, ergosterol ordersDPPC chains more effectively than cholesterol. On the otherhand, ergosterol is less effective than cholesterol in promotinglo-phase domains in ld (and so) DPPC bilayers. Therefore, comparedto cholesterol, ergosterol is more effective in inducing chainconformational order although less effective in promoting lateralpacking order in the liquid phase. It is of interest that thesterols affect conformational and lateral packing order differently;the interaction between sterol and lipid molecules is of dualnature.

A partial phase diagram was obtained from the NMR spectra andthe DSC thermograms. It exhibits both so+lo and ld+lo coexistenceregions with a clear three-phase line separating them. In contrastto earlier NMR phase diagram determinations, we have been ablein this study to definitively locate and characterize the ld+lophase coexistence region. Our observation of ld+lo phase coexistenceprovides evidence that two liquid crystalline phases can coexisteven in model membranes containing no proteins. Thus, raftsin cell membranes may be strongly influenced by lipid/lipidinteractions. Distances between ld/lo domain interfaces of 30–80nm are typical of DPPC/ergosterol membranes. Such dimensionsare also typical of "rafts" in cell membranes (Kusumi et al.,2004).

ACKNOWLEDGEMENTS

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

We are grateful to Markus Vist and Jim Davis for sending ustheir unpublished DPPC-d62/cholesterol data and to Ole Mouritsenfor "domain" discussions. M.J.Z. is most grateful for discussionswith Kevin Barrow, Hans Coster, and Milan Hoefer; importantcorrespondence from Guenther Daum; and both discussions anddetailed correspondence related to earlier research from TillBoecking. J.T. thanks Chris Beh for his input on yeast membranes.

This work was supported by research grants from the NaturalSciences and Engineering Research Council of Canada. MEMPHYS-Centerfor Biomembrane Physics is supported by the Danish NationalResearch Foundation.

FOOTNOTES

Ya-Wei Hsueh's present address is Dept. of Physics, NationalCentral University, Chungli 320, Taiwan.

Kyle Gilbert's present address is Dept. of Physics, Universityof Western Ontario, London, Ontario, Canada N6A 5B8.

Submitted on August 17, 2004; accepted for publication November 19, 2004.

REFERENCES

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

Bagnat, M., A. Chang, and K. Simons. 2001. Plasma membrane proton ATPase Pma1p requires raft association for surface delivery in yeast. Mol. Biol. Cell. 12:4129–4138.[Abstract/Free Full Text]

Bagnat, M., S. Keranen, A. Shevchenko, and K. Simons. 2000. Lipid rafts function in biosynthetic delivery of proteins to the cell surface in yeast. Proc. Nat. Acad. Sci. USA 97:3254–3259.[Abstract/Free Full Text]

Bottema, C. D. K., R. J. Rodriguez, and L. W. Parks. 1985. Influence of sterol structure on yeast plasma membrane properties. Biochim. Biophys. Acta. 813:313–320.[Medline]

Carrington, A., and A. D. McLachlan. 1967. Introduction to Magnetic Resonance. Harper & Row, New York, NY.

Davis, J. H., K. R. Jeffrey, M. Bloom, M. I. Valic, and T. P. Higgs. 1976. Quadrupolar echo deuteron magnetic resonance spectroscopy in ordered hydrocarbon chains. Chem. Phys. Lett. 42:390–394.[CrossRef]

Eisenkolb, M., C. Zenzmaier, E. Leitner, and R. Schneiter. 2002. A specific structural requirement for ergosterol in long chain fatty acid synthesis mutants important for maintaining raft domains in yeast. Mol. Biol. Cell. 13:4414–4428.[Abstract/Free Full Text]

Endress, E., S. Bayerl, K. Prechtel, C. Maier, R. Merkel, and T. M. Bayerl. 2002. The effect of cholesterol, lanosterol, and ergosterol on lecithin bilayer mechanical properties at molecular and microscopic dimensions: a solid-state NMR and micropipet study. Langmuir. 18:3293–3299.[CrossRef]

Filippov, A., G. Orädd, and G. Lindblom. 2003. The effect of cholesterol on the lateral diffusion of phospholipids in oriented bilayers. Biophys. J. 84:3079–3086.[Abstract/Free Full Text]

Huang, T. H., C. W. Lee, S. K. Das Gupta, A. Blume, and R. G. A. Griffin. 1993. A ¹³C and ²H nuclear magnetic resonance study of phosphatidylcholine/cholesterol interactions: characterization of liquid-gel phases. Biochemistry. 32:13277–13287.[CrossRef][Medline]

Ipsen, J. H., G. Karlstrom, O. G. Mouritsen, H. Wennerstrom, and M. J. Zuckermann. 1987. Phase-equilibria in the phosphatidylcholine-cholesterol system. Biochim. Biophys. Acta. 905:162–172.[Medline]

Kuebler, E., H. G. Dohlman, and M. P. Lisanti. 1996. Identification of Triton X-100 insoluble membrane domains in the yeast Saccharomyces cerevisiae. J. Biol. Chem. 271:32975–32980.[Abstract/Free Full Text]

Kusumi, A., I. Koyama-Honda, and K. Suzuki. 2004. Molecular dynamics and interactions for creation of stimulation-induced stabilized rafts from small unstable steady-state rafts. Traffic. 5:213–230.[CrossRef][Medline]

Lafleur, M., B. Fine, E. Sternin, P. R. Cullis, and M. Bloom. 1989. Smoothed orientational order profile of lipid bilayers by ²H-nuclear magnetic resonance. Biophys. J. 56:1037–1041.[Abstract/Free Full Text]

Longley, R. P., A. H. Rose, and B. A. Knights. 1968. Composition of the protoplast membrane from Saccharomyces cerevisiae. Biochem. J. 108:401–412.[Medline]

Ohvo-Rekilä, H., B. Ramstedt, P. Leppimäki, and J. P. Slotte. 2002. Cholesterol interactions with phospholipids in membranes. Prog. Lipid Res. 41:66–97.[CrossRef][Medline]

Patton, J. L., and R. L. Lester. 1991. The phosphoinositol sphingolipids of Saccharomyces cerevisiae are highly localized in the plasma membrane. J. Bacteriol. 173:3101–3108.[Abstract/Free Full Text]

Rodriguez, R. J., C. Low, C. D. Bottema, and L. W. Parks. 1985. Multiple functions for sterols in Saccharomyces cerevisiae. Biochim. Biophys. Acta. 837:336–343.[Medline]

Schneiter, R., B. Brügger, R. Sandhoff, G. Zellnig, A. Leber, M. Lampl, K. Athenstaedt, C. Hrastnik, S. Eder, G. Daum, F. Paltauf, F. T. Wieland, and S. D. Kohlwein. 1999. Electrospray ionization tandem mass spectrometry (ESI-MS/MS) analysis of the lipid molecular species composition of yeast subcellular membranes reveals acyl chain-based sorting/remodeling of distinct molecular species en route to the plasma membrane. J. Cell Biol. 146:741–754.[Abstract/Free Full Text]

Smondyrev, A. M., and M. L. Berkowitz. 2001. Molecular dynamics simulation of the structure of dimyristoylphosphatidylcholine bilayers with cholesterol, ergosterol, and lanosterol. Biophys. J. 80:1649–1658.[Abstract/Free Full Text]

Thewalt, J. L., and M. Bloom. 1992. Phosphatidylcholine: cholesterol phase diagrams. Biophys. J. 63:1176–1181.[Abstract/Free Full Text]

Tuller, G., T. Nemec, C. Hrastnik, and G. Daum. 1999. Lipid composition of subcellular membranes of an FY1679-derived haploid yeast wild-type strain grown on different carbon sources. Yeast. 15:1555–1564.[CrossRef][Medline]

Urbina, J. A., S. Pekerar, H. B. Le, J. Patterson, B. Montez, and E. Oldfield. 1995. Molecular order and dynamics of phosphatidylcholine bilayer membranes in the presence of cholesterol, ergosterol and lanosterol: a comparative study using ²H-, ¹³C- and ³¹P-NMR spectroscopy. Biochim. Biophys. Acta. 1238:163–176.[Medline]

Varma, R., and S. Mayor. 1998. GPI-anchored proteins are organized in submicron domains at the cell surface. Nature. 394:798–801.[CrossRef][Medline]

Veatch, S., and S. Keller. 2003. Separation of liquid phases in giant vesicles of ternary mixtures of phospholipids and cholesterol. Biophys. J. 85:3074–3083.[Abstract/Free Full Text]

Veatch, S. L., I. V. Polozov, K. Gawrisch, and S. L. Keller. 2004. Liquid domains in vesicles investigated by NMR and fluorescence microscopy. Biophys. J. 86:2910–2922.[Abstract/Free Full Text]

Vist, M., and J. H. Davis. 1990. Phase equilibria of cholesterol/dipalmitoylphosphatidylcholine mixtures: ²H nuclear magnetic resonance and differential scanning calorimetry. Biochemistry. 29:451–464.[CrossRef][Medline]

Xu, X., R. Bittman, G. Duportail, D. Heissler, C. Vilcheze, and E. London. 2001. Effect of the structure of natural sterols and sphingolipids on the formation of ordered sphingolipid/sterol domains (rafts). Comparison of cholesterol to plant, fungal, and disease-associated sterols and comparison of sphingomyelin, cerebrosides, and ceramide. J. Biol. Chem. 276:33540–33546.[Abstract/Free Full Text]

Zinser, E., F. Paltauf, and G. Daum. 1993. Sterol composition of yeast organelle membranes and subcellular distribution of enzymes involved in sterol metabolism. J. Bacteriol. 175:2853–2858.[Abstract/Free Full Text]

Zinser, E., C. D. Sperka-Gottlieb, E. V. Fasch, S. D. Kohlwein, F. Paltauf, and G. Daum. 1991. Phospholipid synthesis and lipid composition of subcellular membranes in the unicellular eukaryote Saccharomyces cerevisiae. J. Bacteriol. 173:2026–2034.[Abstract/Free Full Text]

This article has been cited by other articles:

K. Sabatini, J.-P. Mattila, and P. K. J. Kinnunen
Interfacial Behavior of Cholesterol, Ergosterol, and Lanosterol in Mixtures with DPPC and DMPC
Biophys. J., September 1, 2008; 95(5): 2340 - 2355.
[Abstract] [Full Text] [PDF]

H. McConnell and A. Radhakrishnan
Molecular Motion at the Critical Point in Lipid Membranes
Biophys. J., July 15, 2008; 95(2): L22 - L24.
[Abstract] [Full Text] [PDF]

R. Krivanek, L. Okoro, and R. Winter
Effect of Cholesterol and Ergosterol on the Compressibility and Volume Fluctuations of Phospholipid-Sterol Bilayers in the Critical Point Region: A Molecular Acoustic and Calorimetric Study
Biophys. J., May 1, 2008; 94(9): 3538 - 3548.
[Abstract] [Full Text] [PDF]

Y.-W. Hsueh, M.-T. Chen, P. J. Patty, C. Code, J. Cheng, B. J. Frisken, M. Zuckermann, and J. Thewalt
Ergosterol in POPC Membranes: Physical Properties and Comparison with Structurally Similar Sterols
Biophys. J., March 1, 2007; 92(5): 1606 - 1615.
[Abstract] [Full Text] [PDF]

V. Shahedi, G. Oradd, and G. Lindblom
Domain-Formation in DOPC/SM Bilayers Studied by pfg-NMR: Effect of Sterol Structure
Biophys. J., October 1, 2006; 91(7): 2501 - 2507.
[Abstract] [Full Text] [PDF]

S. L. Veatch, K. Gawrisch, and S. L. Keller
Closed-Loop Miscibility Gap and Quantitative Tie-Lines in Ternary Membranes Containing Diphytanoyl PC
Biophys. J., June 15, 2006; 90(12): 4428 - 4436.
[Abstract] [Full Text] [PDF]

M. Fidorra, L. Duelund, C. Leidy, A. C. Simonsen, and L.A. Bagatolli
Absence of Fluid-Ordered/Fluid-Disordered Phase Coexistence in Ceramide/POPC Mixtures Containing Cholesterol
Biophys. J., June 15, 2006; 90(12): 4437 - 4451.
[Abstract] [Full Text] [PDF]

L. Silva, A. Coutinho, A. Fedorov, and M. Prieto
Competitive Binding of Cholesterol and Ergosterol to the Polyene Antibiotic Nystatin. A Fluorescence Study
Biophys. J., May 15, 2006; 90(10): 3625 - 3631.
[Abstract] [Full Text] [PDF]

				H. McConnell and A. Radhakrishnan Molecular Motion at the Critical Point in Lipid Membranes Biophys. J., July 15, 2008; 95(2): L22 - L24. [Abstract] [Full Text] [PDF]

				R. Krivanek, L. Okoro, and R. Winter Effect of Cholesterol and Ergosterol on the Compressibility and Volume Fluctuations of Phospholipid-Sterol Bilayers in the Critical Point Region: A Molecular Acoustic and Calorimetric Study Biophys. J., May 1, 2008; 94(9): 3538 - 3548. [Abstract] [Full Text] [PDF]

				Y.-W. Hsueh, M.-T. Chen, P. J. Patty, C. Code, J. Cheng, B. J. Frisken, M. Zuckermann, and J. Thewalt Ergosterol in POPC Membranes: Physical Properties and Comparison with Structurally Similar Sterols Biophys. J., March 1, 2007; 92(5): 1606 - 1615. [Abstract] [Full Text] [PDF]

				V. Shahedi, G. Oradd, and G. Lindblom Domain-Formation in DOPC/SM Bilayers Studied by pfg-NMR: Effect of Sterol Structure Biophys. J., October 1, 2006; 91(7): 2501 - 2507. [Abstract] [Full Text] [PDF]

				S. L. Veatch, K. Gawrisch, and S. L. Keller Closed-Loop Miscibility Gap and Quantitative Tie-Lines in Ternary Membranes Containing Diphytanoyl PC Biophys. J., June 15, 2006; 90(12): 4428 - 4436. [Abstract] [Full Text] [PDF]

				M. Fidorra, L. Duelund, C. Leidy, A. C. Simonsen, and L.A. Bagatolli Absence of Fluid-Ordered/Fluid-Disordered Phase Coexistence in Ceramide/POPC Mixtures Containing Cholesterol Biophys. J., June 15, 2006; 90(12): 4437 - 4451. [Abstract] [Full Text] [PDF]

				L. Silva, A. Coutinho, A. Fedorov, and M. Prieto Competitive Binding of Cholesterol and Ergosterol to the Polyene Antibiotic Nystatin. A Fluorescence Study Biophys. J., May 15, 2006; 90(10): 3625 - 3631. [Abstract] [Full Text] [PDF]