Biphenyl Bicelle Disks Align Perpendicular to Magnetic Fields on Large Temperature Scales: A Study Combining Synthesis, Solid-State NMR, TEM, and SAXS

doi:10.1529/biophysj.106.097758

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Biphenyl Bicelle Disks Align Perpendicular to Magnetic Fields on Large Temperature Scales: A Study Combining Synthesis, Solid-State NMR, TEM, and SAXS

Cécile Loudet^*, Sabine Manet^*, Stéphane Gineste, Reïko Oda^*, Marie-France Achard and Erick J. Dufourc^*

^* UMR 5248 CBMN, CNRS-Université Bordeaux 1-ENITAB, Institut Européen de Chimie et Biologie, Pessac, France; and UPR 8641, Centre de Recherche Paul Pascal, CNRS, Pessac, France

Correspondence: Address reprint requests to Erick J. Dufourc, UMR 5248 CBMN, CNRS-Université Bordeaux 1-ENITAB, IECB, 2 rue Robert Escarpit, 33607 Pessac, France. Tel./Fax: 33-5-4000-2218; E-mail: e.dufourc{at}iecb.u-bordeaux.fr.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

A phosphatidylcholine lipid (PC) containing a biphenyl groupin one of its acyl chains (1-tetradecanoyl-2-(4-(4-biphenyl)butanoyl)-sn-glycero-3-PC,TBBPC) was successfully synthesized with high yield. Water mixturesof TBBPC with a short-chain C₆ lipid, dicaproyl-PC (DCPC), leadto bicelle systems formation. Freeze-fracture electron microscopyevidenced the presence of flat bilayered disks of 800 Ådiameter for adequate composition, hydration, and temperatureconditions. Because of the presence of the biphenyl group, whichconfers to the molecule a positive magnetic anisotropy ${Delta}$ ${chi}$ , thedisks align with their normal, n, parallel to the magnetic fieldB₀, as directly detected by ³¹P, ¹⁴N, ²H solid-state NMR andalso using small-angle x-ray scattering after annealing in thefield. Temperature-composition and temperature-hydration diagramswere established. Domains where disks of TBBPC/DCPC align withtheir normal parallel to the field were compared to chain-saturatedlipid bicelles made of DMPC(dimyristoylPC)/DCPC, which orientwith their normal perpendicular to B₀. TBBPC/DCPC bicelles existon a narrow range of long- versus short-chain lipid ratios (3%)but over a large temperature span around room temperature (10–75°C),whereas DMPC/DCPC bicelles exhibit the reverse situation, i.e.,large compositional range (22%) and narrow temperature span(25–45°C). The two types of bicelles present orientingproperties up to 95% dilution but with the peculiarity thatwater trapped in biphenyl bicelles exhibits ordering propertiestwice as large as those observed in the saturated-chains analog,which offers very interesting properties for structural studieson hydrophilic or hydrophobic embedded biomolecules.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

Understanding the function of proteins is tightly linked tothe determination of protein atomic structure and dynamics.In studying membrane proteins, finding the topology/orientationat or in the membrane lipid bilayer is also of first importance.Among all spectroscopic techniques leading to such information,NMR, both in its solution and solid-state versions, is a powerfultechnique to study proteins in a membrane environment (1–3).Several innovative models of biological membranes such as micelles(4,5) and multilamellar (6) or unilamellar (7) vesicles werethus customized to investigate structure and dynamics of integralmembrane proteins having single or multiple transmembrane segments(8). To improve the spectral NMR resolution and particularlyto determine the orientation of membrane proteins, it is interestingto orient these models in a magnetic field, B₀. Membrane systemssandwiched between glass plates that are macroscopically orientedin the magnetic field are tested, but a difficult control ofthe sample hydration limits their use (9,10). Since the mid1980s, a new membrane model, called a "bicelle," has becomevery popular (11,12) because it orients spontaneously in magneticfields and because both magic angle spinning and wide-line NMRexperiments may be performed with the same well-hydrated sample(13,14). Bicelles represent an intermediate model membrane betweenlipid vesicles and classical micelles. They are composed ofmixtures of long-chain phospholipids (14–18 carbons) andshort-chain phospholipids (6–8 carbons) and may take severalmorphologies depending on composition (X = [long chain]/[totallipid]), temperature, and hydration (h = water mass/total mass).Disk-shaped, cylindrical "wormlike" micelles and perforatedlamellae have been reported (15–22). Disk dimensions of30–60 nm diameter and 4–5 nm thickness have beenmeasured by electron microscopy (15). Because of the negativeanisotropy of the diamagnetic susceptibility of dialkanoylphospholipidsin the whole edifice, ${Delta}$ ${chi}$ ( ${Delta}$ ${chi}$ = ${chi}$ _// – ${chi}$ , where ${chi}$ _// and ${chi}$ respectivelyrepresent the magnetic susceptibility parallel and perpendicularto the long lipid axis), bicelles are aligned by high magneticfields, the normal, n, to the bilayer disk orienting perpendicularto the field direction B₀. Temperature-hydration-compositiondiagrams for which bicelles made of DMPC (dimyritoylphosphatidylcholine)and DCPC (dicaproylphosphatidylcholine) orient in magnetic fieldsare now well characterized (15,19). Their domain of existenceis encountered for DMPC molar contents varying from 65% to 87%,temperatures in the range 25–45°C, and from 40% to95% hydration (w/w). These model membranes display many advantagesfor biomolecular structural studies, especially if their orientationin the magnetic field can be modulated as a real "moleculargoniometer" (23–25). Although the direction of alignmentcan be changed under variable-angle rapid sample spinning (26),a uniform and spontaneous alignment of static samples is mostdesirable. Consequently, investigations are conducted to changethe natural alignment of the bicelle's normal from perpendicularto parallel relative to B₀. Two approaches have been used toachieve this goal: the first is to use a paramagnetic lanthanide(27–30) such as Eu³⁺, Tm³⁺, or Yb³⁺, but the line broadeningpromoted by these cations may be a concern. The second is theaddition of molecules with a large positive ${Delta}$ ${chi}$ , such as peptides(31) or amphiphilic aromatic compounds (32), because phenylrings have a strong positive ${Delta}$ ${chi}$ (33,34). However, large amountsof additive are required to obtain the new orientation and mayperturb the membrane. To overcome these problems, Cho and co-workers(35,36) developed a modified phosphatidylcholine (PC), the dodecanoyl-2-(4-(4-biphenyl)butanoyl)-sn-glycero-3-phosphocholine(DBBPC), in which one of the aliphatic chains contains a biphenylunit. This phospholipid has a large positive ${Delta}$ ${chi}$ that naturallyinduces the new orientation with the bicelle normal aligningparallel to B₀. It was shown that mixtures of DBBPC/DCPC witha ratio close to 6 can form bicellar solutions that are stablefrom 10°C to 54°C (35).

In our study, we report a new system of bicelles composed witha peculiar phospholipid TBBPC (tetradecanoyl-2-(4-(4-biphenyl)butanoyl)-sn-glycero-3-phosphocholineand DCPC. The C₁₂ aliphatic chain of DBBPC was replaced by aC₁₄ to be closer to the chain length of natural membrane lipids.Preliminary results have already been reported (37). After synthesizingthis new lipid TBBPC, we used wide-line ³¹P, ¹⁴N, and ²H solid-stateNMR to evaluate lipid polymorphism and dynamics of this binarysystem on variation of lipid ratio, temperature, and hydration.We also showed that under fixed conditions of temperature, hydration,and composition, discoidal nano-objects can be observed by freeze-fractureelectron microscopy and that x-rays (SAXS) can characterizetheir specific orientation after alignment in the magnetic field.Diagrams and dynamics of water trapped in TBBPC/DCPC bicelleswere also compared to similar data already reported from "classical"DMPC/DCPC systems (15,19).

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

Chemicals
1,2-Dimyristoylphosphatidylcholine (DMPC), 1,2-dicaproylphosphatidylcholine(DCPC), and lyso-myristoylphosphatidylcholine (lyso-MPC) werepurchased from Avanti Polar Lipids (Birmingham, AL); the othercompounds were purchased from Sigma-Aldrich Chemicals (St. Quentin-Fallavier,France); all these starting materials were used without furtherpurification. Deuterated water (D₂O) was obtained from Eurisotop(Saint Aubin, France).

Synthesis of the TBBPC lipid
1-Tetradecanoyl-2-(4-(4-biphenyl)butanoyl)-sn-glycero-3-phosphatidylcholine(TBBPC) was synthesized by following the procedures used forthe preparation of the 1-dodecanoyl-2-BBPC as reported by Tanet al. (36) (see Fig. 1 for the TBBPC synthesis scheme). Theproduct was then purified twice on a flash silica gel column,with CHCl₃:CH₃OH:H₂O (65:35:4, v/v) as eluent. Fractions containingthe lipid were pooled up and the solvent removed by evaporationand freeze-drying. Finally, a white powder of TBBPC was obtainedwith a 70% yield: ¹H NMR (400 MHz, CDCl₃), ${delta}$ (ppm) 7.49 (d, 2)H,Ar), 7.44 (d, 2H, Ar), 7.34 (m, 2H, Ar), 7.24 (m, 2H, Ar), 7.17(d, 2H, Ar), 5.15 (m, 1H, CH), 4.32 (dd, 1H, CH), 4.20 (m, 2H,POCH₂CH₂N), 4.06 (dd, 1H, CH), 3.88 (m, 2H, CH₂OCO), 3.66 (m,2H, CH₂N), 3.23 (s, 9H, N(CH₃)₃), 2.6 (t, 2H, CH₂), 2.29 (t,2H, CH₂), 2.17 (t, 2H, CH₂), 1.88 (t, 2H, CH₂), 1.47 (m, 2H,CH₂), 1.15 (s, 20H, fatty CH₂), 0.8 (t, 3H, CH₃); ¹³C NMR (400MHz, CDCl₃), ${delta}$ (ppm): 173.83, 173.08, 141.06, 140.68, 139.12,129.15, 129.1, 128.98, 128.96, 127.32, 127.13, 70.92, 66.55,63.66, 63.16, 59.46, 54.63, 34.83, 34.33, 33.87, 32.14, 31.17,29.90, 29.87, 29.75, 29.58, 29.53, 29.37, 26.74, 25.08, 22.91,14.35; mass spectrum (ESI, full ms): m/z 689.5 (calculated 689);FT-IR (analysis was performed in between two ZnSe pellets, withTBBPC liposomes hydrated in water, and data were recorded withan OPUS IFS 55 Bruker), ${nu}$ _stretching (cm^–1): 2923 (CH_2,asym), 2852 (CH_{2, sym}), 1732 (C=O), 1378 (O=C–CH₃), 1229(O–C=O), 1087 and 1067 (O–CH₂).

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FIGURE 1 Synthetic reaction scheme for the TBBPC phospholipid, obtained from an esterification reaction between 1-myristoyl-2-hydroxy-sn-glycero-3-phosphocholine and the 4-(4-biphenyl)butanoic acid; this last one was previously synthesized by a Friedel and Craft acylation and a Clemmensen reduction (36

). 1, succinic anhydride; 2, biphenyl; 3, 4-(4-biphenyl)-4-oxobutanoic acid; 4, 4-(4-biphenyl)butanoic acid; 5, 1-myristoyl-2-hydroxy-sn-glycero-3-phosphocholine; 6, 1-tetradecanoyl-2-(4-(4-biphenyl)butanoyl)-sn-glycero-3-phosphatidylcholine (TBBPC).

Bicelles preparation
For ³¹P or ²H NMR experiments, appropriate amounts of phospholipidswere weighted to obtain mole contents, X, of TBBPC in the mixtureranging from 80% to 95% (molar ratio q = [TBBPC]/[DCPC] varyingfrom 4 to 19). A suitable volume of deuterated water, D₂O, containing100 mM NaCl was added to obtain a lipid hydration, h, rangingfrom 70% to 95% (w/w). Hydration is defined as the mass of waterover the total mass of the system (phospholipids and water).Hydrated samples were centrifuged at 6500 rpm for 5 min andvigorously stirred in a vortex mixer. The samples were thenfrozen in liquid nitrogen for 30 s, heated at 50°C for 10min in a water bath, vigorously stirred in a vortex, and centrifugedagain at 6500 rpm for 5 min. This cycle was repeated three timesuntil a viscous (milky or translucent, depending on X) suspensionwas obtained at room temperature. Each preparation was thentransferred into a 4-mm NMR tube (80 µl, ZrO₂ rotor) forwide-line NMR experiments; the less hydrated samples (h = 70%)were transferred in the rotor according to the following procedure:hydrated samples were prepared in a conical plastic microtube(1.5 ml) that was frozen in liquid nitrogen and then transferredinto the 4-mm rotor using a home-made funnel. The latter allowsfilling the rotor homogeneously, without air bubbles, with centrifugationat 2000 rpm for 30 s at room temperature. For ¹⁴N NMR experiments,DMPC/DCPC and TBBPC/DCPC systems were prepared with X = 78%in 100 mM KCl and X = 85.7% in 100 mM NaCl, respectively, witha total lipid hydration of 90% (w/w) in D₂O. The same samplepreparation, as described above, was applied. For electron microscopyanalyses, TBBPC/DCPC mixtures were prepared with h = 90% andX = 85.7%. For SAXS analyses, TBBPC/DCPC bicelles were preparedwith h = 80% and X = 87.5%.

NMR spectroscopy
NMR experiments were carried out on Bruker Avance 500-, 400-,and 300-MHz spectrometers. ³¹P NMR spectra were acquired at162 MHz, using a phase-cycled Hahn-echo pulse sequence withgated broadband proton decoupling (38). ²H NMR experiments ondeuterated water were performed at 61.5 MHz and 46 MHz, by meansof a one-pulse sequence. ¹⁴N NMR experiments were acquired at36 MHz, using a quadrupolar echo pulse sequence (39). Typicalacquisition parameters were as follows: spectral window of 32kHz for ³¹P NMR, 2 kHz for ²H NMR, and 100 kHz for ¹⁴N NMR; ${pi}$ /2 pulse widths of 14.5 µs for ³¹P NMR, 17 µs for²H NMR, and 10 µs for ¹⁴N NMR; interpulse delays wereof 50 µs for ³¹P NMR and 200 µs for ¹⁴N NMR. A recycledelay of 5 s was used for ³¹P and ²H NMR, and for ¹⁴N NMR experimentsit was set to 0.2 s. Typically, 350 scans were recorded forphosphorus spectra with deuterium (D₂O) lock, 40 scans for deuteriumspectra, and 40,000 scans for nitrogen spectra. A line broadeningof 50 Hz was usually applied before Fourier transformation forphosphorus spectra, from 2 to 5 Hz for ²H NMR experiments, andfrom 20 to 100 Hz for ¹⁴N RMN. Quadrature detection was usedin all cases. Samples were allowed to equilibrate at least 30min at a given temperature (ranging 0°C to 80°C forTBBPC bicelles) before the NMR signal was acquired; the temperaturewas regulated to ±1°C. All the thermal variationswere performed by increasing the temperature from 25°C to80°C and by decreasing the temperature from 25°C to0°C.

Freeze-fracture electron microscopy
Freeze-fracture experiments were performed with a Balzers BAF300 vacuum chamber (Balzers, Liechtenstein). A small dropletof the TBBPC/DCPC preparation was sandwiched between two copperspecimen holders at room temperature. The sandwich was thenfrozen with liquid propane cooled with liquid nitrogen. Thefrozen sandwich was additionally fixed to a transport unit underliquid nitrogen and transferred to the fracture replicationstage in a chamber that was then pumped down to 2 x 10^–6mBar at –145°C. Immediately after fracturing, replicationtook place by first shadowing with platinum/carbon at a 45°angle and then with carbon deposition at 90°. The samplewas then allowed to warm at room temperature. Replicas wereretrieved from the fractural plane and cleaned in ethanol/water(2:1, v/v) and mounted on 300-mesh copper grids. Observationswere made with a transmission electron microscope FEI EM120operated at 120 kV. Images were recorded using a SSCCD 2k x2k Gatan camera. The Corel Photo Paint package was used forimage processing. The Scion software was used to measure bicellesize on TEM images, considering each time the longest dimensionof the objects. A histogram was built from these measurementsand analyzed by a Gaussian function with Origin software.

Small-angle x-ray scattering
A Rigaku Nanoviewer (Micro-source generator, MicroMax 007, Tokyo,Japan) was used, equipped with a rotating Cu anode generatoroperated at 40 kV and 20 mA, coupled with a Confocal MaxfluxMirror. The two-dimensional scattering pattern was measuredusing a Mercury CCD camera, and the distance sample-detectorwas fixed to 425 mm (0 $≤$ q $≤$ 0.35 Å^–1). The solutionswere sealed in glass capillaries with a 1.5 mm diameter (GlaskapillarenGLAS, Germany) and placed in the sample chamber regulated at35°C. The exposure time was 600 s, and the scattering intensitiesfrom the buffer solution as well as the detector dark were measuredseparately and subtracted from that of samples. The obtainedtwo-dimensional scattering patterns were analyzed with RigakuNanoviewer software, which allows an integration of the signalintensity either circularly (over 360°) or linearly (at0° or 90°). The resulting data were then treated withOrigin software.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

In the first section, the binary system TBBPC/DCPC is described:after the TBBPC synthesis several samples of the mixture wereprepared by varying the mole fraction of TBBPC, X, the temperature,T, and the hydration, h, and diagrams were further establishedusing phosphorus wide-line NMR. The TBBPC/DCPC disk size wasstatistically determined on TEM images and compared with thatobtained from integration of NMR lines (15,31). Their specificorientation with the bilayer normal, n, parallel to the magneticfield, n//B₀, was confirmed by SAXS analysis after alignmentin B₀. In a second part, the biphenyl bicelles are comparedwith their chain saturated analogs (DMPC/DCPC system): ¹⁴N NMR,²H NMR (of deuterated water), and temperature-composition domains.

Biphenyl bicelles
TBBPC synthesis
The TBBPC phospholipid was successfully synthesized (Fig. 1)with a satisfactory yield (70%). The esterification reactionbetween the lyso-lauroylphosphatidylcholine (C₁₂ aliphatic chain)and the 4-(4-biphenyl)butanoic acid (60% yield) (36), can easilybe applied and with a better yield to a myristoylphosphatidylcholine(C₁₄ aliphatic chain), whose chain length is closer to thatof natural membrane lipids.

³¹P NMR spectroscopy of TBBPC-DCPC binary systems (depending on X and h)
Samples with TBBPC mole fractions ranging from X = 80% to X= 95% were prepared with two different hydration conditions,h = 80% and h = 90%, in the presence of 100 mM NaCl. For mostcombinations of individual lipid composition and hydration,the temperature was varied from 0°C to 80°C. Figs. 2and 3 show selected spectra for the different TBBPC/DCPC binarysystems relative to mole fraction of TBBPC, X (for h = 80%,Fig. 2), temperature and hydration (for X = 86%, Fig. 3). Thesespectra display a wide variety of line shapes that are characteristicof pure lipid phases or of a mixture of lipid phases. It mustbe mentioned here that the term "phase" is used in this reportto qualify a change in polymorphism as detected by NMR, whichmay not necessarily correspond stricto sensu to the Gibbs thermodynamicdefinition. Fig. 2 spectra corresponding to X = 80% and T $≥$ 40°Cexhibit a single sharp line centered at 0.9 ppm, close to theisotropic chemical shift of phosphatidylcholine. This singleline reflects the total averaging of the chemical shift anisotropyinteraction because of the presence of small and rapidly tumblingobjects (mixed micelles or very small bicelles). Several spectrapresent two sharp lines with a chemical shift of $~$ 20 ppm and $~$ 5 ppm (see for instance Fig. 2: X = 85.7% for T = 50°C andX = 87.5% from T = 25°C to T = 70°C; or Fig. 3: X =86%, temperatures varying from 10°C to 50°C and hydrationvarying between 70% and 90%). These particular spectra are thesignature of bicelles oriented with their normal to the bilayerparallel to the magnetic field: the major peak may be assignedto phospholipids located in the bilayer plane with their directoraxis oriented parallel to B₀ (assigned to TBBPC in the majority),whereas the smaller peak results from the rapid diffusion oflipids on the highly curved surface at the edge of the bicellardisk (assigned mainly to DCPC). Moreover, we can notice in Fig. 2that for X = 87.5% and temperatures varying from 10°C to70°C, the more the temperature increases, the more the distancebetween the two lines decreases, and the sharper the peaks become,which may be associated with a better macroscopic orientationof the system in the field (15). For X = 85.7%, T = 70°C,h = 80% (Fig. 2) and for X = 86%, T = 50–70°C, h =95% (Fig. 3), these bicelles coexist with an isotropic phase.For X $≥$ 92% with the temperature varying from 25°C to 70°Cand X = 80% for T = 25°C and 35°C (Fig. 2), we mainlyobserve composite spectra with a superimposition of an isotropicline and a broad axially symmetric powder pattern (for T = 25°C, ${Delta}$ ${sigma}$ = 17.5 ppm for X = 80% and ${Delta}$ ${sigma}$ = 33 ppm for X = 92%). The broadspectrum is characteristic of an unoriented lamellar phase.Most of the other spectra combine the superposition of two orthree of the spectral features that correspond to micelles,oriented bicelles, or lamellar phases. For example, for h =70–90% and T = 70°C (Fig. 3, X = 86%), an isotropicphase coexists with an oriented lamellar phase (whose normalis oriented in majority parallel to B₀). We can also point outthe case for X = 85.7% and a temperature below 35°C (Fig. 2),where the spectrum shape is quite odd. We performed spectralsimulations (not shown) and could well account for the shapeassuming a cylindrical symmetry (tubes) (40,41) or using a vesicleof prolate form oriented perpendicular to the field (42). Becausewe could not go further in assignment, and because more detailedstudies (outside the scope of our study) clearly would havebeen needed to explore this domain of temperature and composition,we cannot comment further on such shapes.

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FIGURE 2 Gated proton-broad band decoupled ³¹P NMR spectra of TBBPC/DCPC binary mixtures in 80% D₂O (w/w), 100 mM NaCl. Mole fractions X = [TBBPC]/([TBBPC] + [DCPC]) are indicated on the top. Temperature is indicated on the right hand side of spectra. Each spectrum is the average of 350 scans.

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FIGURE 3 Gated proton broad band decoupled ³¹P-NMR spectra of TBBPC/DCPC binary mixtures in D₂O, 100 mM NaCl for X = 86%. Hydration content is indicated on the top. Hydration, h, is defined as the mass of water over the total mass of the system (phospholipids and water). Temperature is indicated on the right-hand side of spectra. Each spectrum is the average of 350 scans.

Temperature-composition diagrams of TBBPC/DCPC binary systems
Following Raffard and Aussenac and their associates (19

,43

),analysis of ³¹P NMR spectra may be used to build temperature-compositiondiagrams of TBBPC/DCPC for the two different hydration conditions,h = 80% and h = 90%, studied in the presence of 100 mM NaCl(Fig. 4). Domains where a single spectral feature is detectedare indicated in Fig. 4 by bold letters as I (isotropic phase,mixed micelles, or very small bicelles), B (magnetically orientedbicelles), and L (lamellar phase). A solid line as eye guidedelimits the domain where bicelles orient in the magnetic field.The TBBPC/DCPC bicelles exist on a wide temperature span (from10°C to 70°C for h = 80% and from 10°C to 60°Cfor h = 90%) but for a narrow range of lipid composition (from85.7% to 88.9% for h = 80% and from 84% to 86% for h = 90%).Therefore, with increasing hydration, the oriented bicelle domainis reduced a little and shifted toward smaller X values. Foreach hydration condition investigated, bicelles are surroundedby an isotropic domain for low X values and by a lamellar phasefor high TBBPC compositions. Two–phase regions, as a functionof temperature, are observed above and below the bicellar domain.They are composed of an isotropic phase coexisting with an orientedlamellar phase for low temperatures and bicelles or an orientedlamellar phase coexisting with an isotropic phase for high temperatures.Adjacent to the bicelles' existence domain, a phase mixturewith spectra (Fig. 2, top, 85.7%) that may represent objectswith cylindrical or oblate vesicle symmetry is observed (videsupra).

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FIGURE 4 Temperature-composition diagrams of TBBPC-DCPC system for two selected hydration contents (h = 80%, top, and h = 90%, bottom), in the presence of 100 mM NaCl as determined from ³¹P NMR spectra: ( ${blacktriangleup}$ ) single phase of bicelles oriented by the magnetic field; ( ${Delta}$ ) oriented bicelles coexisting with isotropic or unoriented phase; ( ${circ}$ ) composite phase with cylindrical symmetry; ( ${nabla}$ ) isotropic phase coexisting with an oriented lamellar phase; ( ${square}$ ) isotropic phase; ( ${lozenge}$ ) lamellar phase. Mole fractions X are expressed in percentage; the corresponding ratio q = [TBBPC]/[DCPC] is indicated with a double x-scale on top. Single-phase regions are denoted I, B, and L for isotropic, magnetically oriented bicelles, and lamellar phases. Solid and dashed lines respectively delineate purely magnetically oriented bicelle domains from purely lamellar or isotropic phases.

Freeze-fracture electron microscopy and bicelle size
Samples of TBBPC/DCPC bicelles with X = 85.7% and h = 90% (with100 mM NaCl) were observed by freeze-fracture transmission electronmicroscopy. A representative TEM image is shown in Fig. 5 A,where a reasonable monodisperse ensemble of discoidal nano-objectsis observed. These appear with either a white or gray coloration,depending on their initial orientation in the sample beforethe fracture (the shadowing being at 45°): explicative schemes(Fig. 5 B) show that an object parallel to the fracture surfacewill appear in average gray, whereas a perpendicular one willappear white. The uniform color of the object confirms theirdiscoidal form with a flat area (a spherical object would appearwith a pronounced gradation from black to white). The longestdimension of 860 anisotropic objects, coming from two replications,was measured on the collected TEM images, and a size histogramwas built using a step size of 100 Å (Fig. 5 C) and fittedwith a Gaussian function (solid bold line) to characterize themean size. An average diameter of 790 Å, with a half-widthat half-height of 300 Å was obtained. The statisticalsize of TBBPC/DCPC bicelles, measured on TEM images, can becompared to that obtained from ³¹P NMR data by directly integratingthe area under the two sharp peaks, assigned to lipids in theflat area and in the half-torus of the disk (15

,31

). Althoughthis method is rough and also caused by the presence of verysmall peaks on NMR spectra (tentatively attributed to impuritiesfrom possible chain scrambling during synthesis (44

), and notedas asterisks on spectra), which made it difficult to accuratelyperform peak integration, an approximate size of 700 ±100 Å was found from the ³¹P NMR data (T = 25°C),which are in very good agreement with the statistical size determinedon TEM images.

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FIGURE 5 (A) Freeze-fracture electron microscopy image of the TBBPC/DCPC system (X = 85.7%, h = 90% in D₂O (w/w) containing 100 mM NaCl). The sample was frozen from room temperature. The bar in the picture measures 100 nm. (B) Schematic drawing showing the resulting shadows (45°) when a bilayered disk is either parallel or perpendicular to the fracture plane. (C) Histogram of size distribution for the TBBPC/DCPC system (X = 85.7%, h = 90% in D₂O with 100 mM NaCl). Objects were measured on the electron microscopy images, considering each time their longest dimension. Histogram was built with a frequency count for object size of 100 Å and analyzed by a Gaussian function (solid line). A comparison with the size determined from ³¹P NMR data is indicated (dashed line).

Small-angle x-ray scattering of magnetically oriented bicelles
A 1.5-mm-diameter glass capillary was filled with 30 µlof a TBBPC/DCPC bicelles preparation (X = 87.5%, h = 80% in100 mM NaCl) and sealed. This capillary was placed in a rotor,and the whole was set in the NMR probe, regulated at 35°C,so that the capillary is aligned with the magnetic field direction.After 20 min in the magnetic field (11.74 Tesla), the capillarywas transferred in a 35°C water bath, in $~$ 2 min, and thenmounted in the SAXS apparatus, previously regulated at 35°C.X-ray data were acquired in 10 min and are shown in Fig. 6 A(right). As can be seen, the resulting 2D scattering patternconsists of four spots aligned along the z-direction, whichcharacterizes a bilayer normal orientation parallel to B₀ (n//B₀).A control experiment was performed with the same sample withoutmagnetic orientation and shows a classical circular pattern,typical of nonoriented material (Fig. 6 A, left). These two-dimensionalscattering patterns are integrated to yield the I = f(q) graph(where I is the scattering intensity and q the scattering vectorin reciprocal angstroms). Integration is performed as describedin Materials and Methods, i.e., over 0–360° for nonorientedsystems and along the direction parallel (z axis) to the magneticfield (see Fig. 6 A) for systems having been oriented in thefield. Hence, I = f(q) patterns for nonoriented bicelles (dashedline, intensity x 40) and magnetically oriented bicelles (solidline) are shown in Fig. 6 B. A wide peak is found for both nonorientedand oriented bicelles, which is characteristic of a phospholipidbilayer structure (45

–48

). For oriented bicelles, a Braggpeak is found for q = 0.055 Å^–1, which correspondsto a periodicity of 114 Å. This Bragg peak is not detectedfor nonoriented bicelles, as they are dispersed in all directions.It is also noticeable that the intensity of the magneticallyoriented TBBPC/DCPC bicelles is much higher (factor 40) thanthat of the nonoriented ones: in the first case, all the objectsare orienting in the same direction and participate in the x-rayscattering, whereas, in the second case, the bicelles have nospecific orientation, therefore decreasing the number of bicellesparticipating in the coherent x-ray scattering.

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FIGURE 6 (A) SAXS images of TBBPC/DCPC bicelles (X = 87.5%) before (top left) and after (top right) orientation for 20 min in an 11.7-Tesla magnetic field (B₀) at 35°C. The drawings below are to help elucidate the position of the capillary tube in the x-ray setup. (B) I = f(q) profile of TBBPC/DCPC bicelles without orientation in B₀ after a circular integration in the (yz) plane (dashed line, scale x40), and TBBPC/DCPC bicelles after orientation in B₀ (solid line, linear integration relative to the z axis).

TBBPC/DCPC versus DMPC/DCPC bicelles
¹⁴N NMR spectroscopy of TBBPC/DCPC and DMPC/DCPC binary systems
¹⁴N NMR can also be applied on bicelle systems because theyprovide information about the dynamics of the choline head group.DMPC/DCPC and TBBPC/DCPC mixtures were prepared with 90% hydration(X = 80% and X = 85%, respectively), and the temperature wasvaried from 0°C to 70°C. Selected spectra for the twosystems are shown in Fig. 7. The DMPC/DCPC binary system exhibitsthree different spectral features, as a function of temperature:below 20°C, a sharp peak, centered at 0 Hz is observed andreflects an isotropic phase. Between 30°C and 40°C,DMPC/DCPC present two distinct quadrupolar splittings, ${Delta}$ ${nu}$ _Q, whichcharacterize bicelles oriented with their normal perpendicularto the field; the smaller (1.68 kHz at 30°C) is assignedto lipids in the disk edge (half-torus part, mainly DCPC), andthe larger (6.96 kHz at 30°C) to lipids in the flat bilayer(mainly DMPC). Above 40°C, an isotropic line is observedcoexisting with a large quadrupolar splitting (9.62 kHz), specificfor a lamellar phase showing residual magnetic field orientation.The TBBPC/DCPC binary system exhibits the characteristic spectralfeature of oriented bicelles for all the temperatures studied,which is in agreement with the bicelle domain determined by³¹P NMR. The smallest quadrupolar splitting (3.27 kHz at 30°C)is assigned to lipids in the toroidal part (mainly DCPC), andthe largest (13.17 kHz at 30°C) to lipids in the disk (mainlyTBBPC). We can notice that on increasing temperature, the outersplitting becomes narrower, whereas the inner increases. Itis interesting to remark that quadrupolar splittings correspondingto the TBBPC/DCPC system are nearly twice as large as thoseof DMPC/DCPC, at the same temperature. This is clearly relatedto the (3cos²ß – 1)/2 relation that is boundto the quadrupolar splitting equation (41

,49

), where ßis the angle between the bilayer normal and the magnetic fielddirection: for "classical" bicelle systems ß = 90°,whereas ß = 0° for the biphenyl analog. Findinga ratio of $~$ 2 between TBBPC/DCPC and DMPC/DCPC quadrupolar splittingsis also an indirect control of a change in magnetic orientationby 90° on going from one system to the other. A more detailedlook at this ratio indicates that it is slightly lower than2, suggesting that the choline head group in TBBPC possessesa slightly greater motional freedom or a slightly differentorientation in comparison to that in DMPC.

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FIGURE 7 ¹⁴N NMR spectra of DMPC/DCPC bicelles and TBBPC/DCPC bicelles in 80% D₂O (w/w) containing, respectively, 100 mM NaCl and 100 mM KCl, X = 78% for DMPC/DCPC, and X = 87.5% for TBBPC/DCPC. Temperature is indicated on the right hand side of spectra. Each spectrum is the average of 40,000 scans.

²H NMR spectroscopy of D₂O in TBBPC/DCPC binary systems
Water structure and dynamics were investigated by replacingH₂O by deuterated water, D₂O, in some samples studied by phosphorusNMR. ²H NMR spectra were recorded for three hydration contents(70%, 80%, and 90%) over a large temperature variation (from0°C to 80°C) with X = 86%. For all hydration contents,a single small quadrupolar splitting is detected for temperaturesranging from 10°C to 70°C. This reflects water moleculesthat are oriented on average around the bicelles, in concordancewith the oriented bicellar domains established by ³¹P NMR forh = 80% and h = 90% (see Fig. 4). Fig. 8 reports the D₂O quadrupolarsplitting in the biphenyl bicelles as a function of temperatureand hydration. The quadrupolar splitting values range from 13Hz to 186 Hz: for a fixed TBBPC mole fraction, it increaseswith temperature and with dehydration. A comparison with theD₂O quadrupolar splittings observed in DMPC/DCPC bicelles, reportedby Arnold et al. (15

), is plotted for h = 80% (X = 78%), inFig. 8. For chain-saturated bicelles, ${Delta}$ ${nu}$ _Q varies from 24 Hz at30°C to 46 Hz at 39°C, whereas for biphenyl bicelles,it varies from 74 Hz at 30°C to 85 Hz at 40°C. The valuesfor the biphenyl system are more than twice as large, whichis again related to the specific orientation of each type ofbicelle (it induces at least a factor 2 between the quadrupolarsplittings). This is particularly interesting for structuralstudies where soluble molecules are trapped in the organizedwater medium: one will thus measure more accurately residualdipolar couplings on a wider thermal span (10–70°C).

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FIGURE 8 Quadrupolar splitting (Hz) of deuterated water in TBBPC/DCPC mixtures (containing 100 mM NaCl for X = 86%) as a function of the temperature (°C) for 70% (solid line), 80% (dashed line), and 90% (dotted line) hydration. These results are compared to those of DMPC/DCPC bicelles for h = 80% ( ${Delta}$ ), reported by Arnold et al. (15

TBBPC/DCPC versus DMPC/DCPC diagrams
The composition-temperature and temperature-hydration diagramsestablished for TBBPC/DCPC system can be directly compared tothose of DMPC/DCPC system, reported by Raffard et al. (19

).Fig. 9 A reports the superposition of the temperature-compositiondomains for which magnetic field orientation occurs, at a fixedhydration, h = 80%. The labels B_// and B respectively standfor bicelles with a normal oriented parallel or perpendicularto the field. Interestingly, the two systems reflect markeddifferences: whereas DMPC/DCPC oriented disks are found forDMPC contents varying from 87% to 65%, TBBPC/DCPC oriented disksare encountered for only a narrow range of compositions, namelyX = 85.7% to X = 88.9%. However, the range of temperatures wherethey are aligned with their normal parallel to the field spansfrom 10°C to 75°C, whereas for DMPC/DCPC this happensonly between 25°C and 45°C. Fig. 9 B reports the superpositionof the temperature-hydration domains at a fixed long-chain lipidcontent, X = 86%. The same symbols as in Fig. 9 A are used.It points out the high stability in temperature of TBBPC/DCPCoriented systems compared to DMPC/DCPC ones. The first onesexist from 10°C to 70°C for 70% hydration, whereas thesecond ones exist from 30°C to 44°C. In both cases,the more hydrated the sample, the more reduced the bicelle domain.Nevertheless, DMPC/DCPC magnetic field orientation is foundonly from 35°C to 42°C at 90% hydration, whereas TBBPC/DCPCbicelles are still orientable from 10°C to 55°C. Forhydration >95%, the two types of bicelles no longer orientin B₀.

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FIGURE 9 (A) Temperature-composition diagrams of DMPC/DCPC (dashed line, hatched area) and TBBPC/DCPC (solid line) in 80% (w/w) D₂O, 100 mM KCl and 100 mM NaCl, respectively, and (B) temperature-hydration diagrams for DMPC/DCPC (X = 78%, 100 mM KCl) TBBPC/DCPC bicelles (X = 85.7%, 100 mM NaCl) as determined by phosphorus NMR. Only magnetic field-oriented bicellar domains are indicated: ( ${Delta}$ ) DMPC system, ( ${blacktriangleup}$ ) TBBPC system. Lines are drawn as eye guides to delineate domains. B_// and B respectively stand for disk normal oriented parallel or perpendicular to the field. DMPC/DCPC data are taken from Raffard et al. (19

It is also noticeable that biphenyl bicelles show a better stabilityin time than saturated chains' bicelles: indeed, they show theircharacteristic oriented spectrum even after 1 mo (or more, ifthey are conserved in the refrigerator at 4°C, spectra notshown), whereas DMPC/DCPC bicelles lose their oriented spectraafter 2 wk. This is mainly because of the slow hydrolysis oflipids, a phenomenon that can be reduced if the ester functionis replaced by an ether (43

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

In this study, two groups of results appear, the first concerningthe physical properties of TBBPC/DCPC systems characterizedby wide-line NMR spectroscopy, freeze-fracture electron microscopy,and SAXS, and the second comparing these new bicelles with thewell-characterized DMPC/DCPC bicelles. They are discussed sequentiallyin the following.

Biphenyl rings lead to n//B₀ oriented bilayered disks with high temperature stability
Major results have been found: 1), disks $~$ 800 Å have clearlybeen evidenced by freeze-fracture electron microscopy, 2), theycan be oriented by magnetic fields in a smectic-like arrangement,i.e., with their normal parallel to the field, and 3), the macroscopicorientation is sufficiently stable that it can be transportedand studied by x-rays where the oriented pattern is clearlydemonstrated. The morphology of bicellar mixtures is very diverseand has been subject to debate in the last decade. Disk-shaped,cylindrical "wormlike" micelles and perforated lamellae havebeen reported (15–22). Because systems have been mostlystudied by solid-state NMR and small-angle neutron scattering(SANS), with which it may be subtle to distinguish between orienteddisks and oriented perforated lamellae, the controversy wentuntil TEM disk images could be taken for the DMPC/DCPC systemwith different cations (15). In fact, the morphology of mixturesof long-chain and short-chain lipids is so rich that disks andcylindrical "wormlike" micelles can be found with the same systembut for different conditions of composition, temperature, orhydration. In our work, the observation of TBBPC/DCPC disksby freeze-fracture electron microscopy rules out the presenceof perforated lamellae: in the latter case, the holes on TEMimages will appear with a gray coloration as for the membranes,and the coexistence of gray and white pictures, as observedin our case, would not be possible. From these TEM images, anaverage size of 790 Å has been statistically determined,which is nearly twice that found for the DMPC/DCPC system ( $~$ 450Å). This clearly scales with the lipid molar ratio q (=[long-chainlipid]/[short-chain lipid]) that is 3.5 for DMPC/DCPC and 6for TBBPC/DCPC: the greater the q, the larger the disk diameter.A rough geometric model has been in fact proposed in which thedisk diameter, ${Phi}$ , can be deducted from q, assuming that long-chainand short-chain lipids segregate in the disk plane and in thehalf-torus, respectively ( ${Phi}$ = aq( ${pi}$ + ( ${pi}$ ² + 8/q)) + 2a) (15,31).By taking 2a ${approx}$ 40 Å, the bilayer thickness of C₁₄ phospholipids(50–52), one would calculate a theoretical diameter of $~$ 820 Å for biphenyl bicelles (q = 6). These values aresomewhat larger than the diameter of the disks, 700 Å,found from integration of NMR lines. However, taking into considerationthat the two lipids probably do not completely segregate inplane and torus areas, we can still conclude that the two techniquesagree well on determining the bicelle sizes. Consequently, thereis a direct link between the lipid composition and the bicellesize.

Of great interest is the fact that bicellar disks, once oriented20 min in the sufficiently strong magnetic field, keep theirmacroscopic orientation for several days and can be studiedby SAXS outside the magnetic field. This technique nicely confirmsthe specific orientation of TBBPC/DCPC bicelles such that theirnormal is parallel with the field, n//B₀, the resulting two-dimensionalscattering pattern exhibiting well-defined spots in the z//B₀direction. Consequently, SAXS can be used as a good alternativeto NMR to specify the orientation of systems such as bicelles.The minimum magnetic field needed for such macroscopic orientationhas not been determined yet. For DMPC/DCPC systems doped withlanthanides, 1 Tesla appeared to be enough for these bicelles(53). Experiments with smaller magnetic fields would be interestingto see whether the TBBPC biphenyl rings help in the orientingcapabilities of bicelles, i.e., weaker fields might be sufficient.The broad peak obtained for the I = f(q) profile characterizesthe phospholipid bilayer structure of the objects, as suggestedby Riske et al. (48). A repeat distance of 114 Å betweentwo oriented TBBPC/DCPC disks has been determined by analyzingthe Bragg peak on the I = f(q) curve (Fig. 6 B). InterestinglyKatsaras et al. clearly evidenced a smectic arrangement forDMPC/DCPC systems doped with Tm³⁺ with a comparable lamellarspacing (116 Å for 77% hydration) (53). Given the DMPCmaximum hydration with a $~$ 60 Å repeat distance, in theabsence of charged additives, such periodicities confirm thehigh hydration of the sample, which makes this system an attractivemodel membrane for structural studies where proteins are embeddedin the water medium.

For the first time, solid-state NMR was performed on TBBPC/DCPCmixtures. It must be mentioned here that Cho and co-workersalso reported ³¹P NMR data on somewhat shorter (C₁₂) biphenylbicelles (DBBPC/DCPC) (35,36). We basically find the same NMRfeatures as they reported: ³¹P NMR spectra made of two sharppeaks with positive chemical shifts, indicative of bilayer normaloriented parallel to the magnetic field direction, the highestpeak being assigned to lipids in the plane and the smallestfor those in the toroidal part. The above authors report a temperaturespan of 10°C to 54°C for which DBBPC/DCPC, q = 6, aremagnetically oriented. Interestingly, we find even larger temperatureranges (10°C to 75°C) for magnetic alignment. This maybe related to the thicker bilayer thickness (C₁₄ acyl chainsinstead of C₁₂ for DBBPC) of the TBBPC/DCPC bicelles that couldbring more stability to the whole edifice. ³¹P NMR has alsoproven to be a nice tool in leading to the construction of temperature-compositionand temperature-hydration diagrams of our system. It clearlyappears that TBBPC/DCPC systems magnetically orient for 85.7–88.9%TBBPC in the system, for temperatures ranging from 10°Cto 75°C at h = 80%, and 84–86% TBBPC content, fortemperatures ranging from 10°C to 55°C at h = 90%. Thetemperature-composition domain where bicelles are magneticallyoriented show a pseudoelliptical shape with the wider span intemperature, which points out their high stability with temperature.As a consequence, they can be easily manipulated because theyexist at ambient temperature. Surrounding this pure domain,one finds biphasic systems such as oriented disks coexistingwith isotropic phases (from the NMR point of view) or systemswith cylindrical symmetry (wormlike micelles?); it is clearthat these regions are complex and would need further investigation.

Biphenyl versus saturated-chain bicelles
Two important results emerge from the comparative study: 1),bicelle disks are found to be much more stable in temperature,and 2), the trapped water is more ordered. Besides the thermalstability, the temperature-composition domain where TBBPC/DCPCbicelles align with their membrane normal parallel to the magneticfield is very narrow (3%) compared to that of DMPC/DCPC bicelles(22%). This can be accounted for by the small flexibility ofthe phenyl chain, which allows little adaptation to the perturbationproduced by the short-chain lipid DCPC that acts as a detergent.Saturated hydrocarbon chains indeed possess more potential degreesof freedom (gauche-trans isomerizations, for instance) to accommodatethe strong curvature promoter made by DCPC. In this respect,DMPC/DCPC bicelles are easier to handle than the TBBPC/DCPCones; for the latter, small weighing errors in the proportionsof the two lipid components will prevent magnetically orienteddisk formation. Conversely, the temperature domain of biphenyl-containingspecies is considerably larger (50°C to 65°C) than thatof DMPC/DCPC (10°C to 15°C). This is mainly becauseof the strong ${Delta}$ ${chi}$ -positive value of the biphenyl moiety, as canbe seen with nematic liquid crystal, which also aligns suchthat the rodlike molecules are parallel to the magnetic fielddirection. Besides ³¹P –NMR, which may routinely be usedto establish the bicelle diagrams, we have shown that ¹⁴N NMRcan also be applied on bicelle systems, even if it takes longer(2 h instead of 20 min for ³¹P NMR) to obtain a very good signal/noiseratio because of the low sensitivity of the nucleus ¹⁴N. Theseexperiments nonetheless present a real interest as they provideinformation about the dynamics of the choline head group. Indeed,because the difference between the ¹⁴N quadrupolar splittingof the two types of bicelles results only from their specificaverage orientation (a factor of $~$ 2), their dynamics can be consideredto be very similar. Consequently, the two phenyl rings on oneof the TBBPC aliphatic chains little affect the mobility ofthe head group compared to that of DMPC.

Interestingly, varying hydration in the temperature range wherebicelles align in the field leads to similar behavior for thetwo systems: an increase in hydration yields to a decrease intheir orienting capabilities, with the limit reached for 95%water content. A minimum packing (maximum swelling of 95%) isnecessary to maintain cooperativity of the objects for keepingtheir alignment with the magnetic field. The ²H NMR analysisof the deuterated water in orienting biphenyl bicelles showsthat ordering properties are more than twice as large as thoseof saturated-chain analogs. Mainly because of the orientationcontribution (factor 2), the water quadrupolar splitting valuesof the biphenyl bicelles are much higher than those of saturated-chainones; this presents a real interest for residual dipolar couplingmeasurements of hydrosoluble peptides or proteins. Moreover,the water in the TBBPC/DCPC system presents ordering propertiesover a very large temperature range (from 10°C to 70°C),which is another advantage for structural studies of hydrophilicbiomolecules. Because of their specific orientation, n//B₀,these new bicelles have been shown to be very promising to studyhydrophobic peptides also and particularly to determine theorientation of amphipathic peptides using wide-line ¹⁵N NMR(37). Nevertheless, the interaction between the two phenyl ringsand transmembrane proteins or peptides has to be further investigated.

CONCLUSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

We have succeeded in synthesizing a new phospholipid, TBBPC,which forms magnetically orientable disks when mixed with DCPC,with an average diameter of 800 Å. These disks orientwith their normal n parallel to B₀ under specific composition,temperature, and hydration conditions. ³¹P, ¹⁴N, ²H solid-stateNMR is a very sensitive technique to map out the domains formagnetic orientation, and SAXS offers a good and original alternativeto NMR for characterizing the specific orientation n//B₀ ofthese new bicelles, once they have been annealed in the field.Comparing to the DMPC/DCPC system, TBBPC/DCPC bicelles are muchmore stable with temperature and offer a very large thermalspan for structural studies of either water-dissolved or membrane-embeddedproteins.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

We gratefully thank Axelle Grelard (UMR 5144 MoBiOS, IECB, Pessac)for her help and her precious advice in NMR spectroscopy, KathelBathany (UMR 5144 MoBiOS, IECB, Pessac) for the mass spectrometryanalysis, and Franck Artzner (UMR 6626, GMCM, Rennes) for hishelp in the analysis of SAXS data.

This work was supported by the Centre National de la RechercheScientifique. We also acknowledge The Aquitaine Region for equipmentfunding.

Submitted on September 19, 2006; accepted for publication December 5, 2006.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

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