Investigating Structural Changes in the Lipid Bilayer upon Insertion of the Transmembrane Domain of the Membrane-Bound Protein Phospholamban Utilizing 31P and 2H Solid-State NMR Spectroscopy

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Investigating Structural Changes in the Lipid Bilayer upon Insertion of the Transmembrane Domain of the Membrane-Bound Protein Phospholamban Utilizing ³¹P and ²H Solid-State NMR Spectroscopy

Paresh C. Dave, Elvis K. Tiburu, Krishnan Damodaran and Gary A. Lorigan

Department of Chemistry and Biochemistry, Miami University, Oxford, Ohio

Correspondence: Address reprint requests to Gary A. Lorigan, Dept. of Chemistry and Biochemistry, Miami University, Oxford, OH 45056. Tel.: 513-529-4703; Fax: 513-529-5715; E-mail: lorigag@muohio.edu.

ABSTRACT

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

Phospholamban (PLB) is a 52-amino acid integral membrane proteinthat regulates the flow of Ca²⁺ ions in cardiac muscle cells.In the present study, the transmembrane domain of PLB (24–52)was incorporated into phospholipid bilayers prepared from 1-palmitoyl-2-oleoyl-sn-glycero-phosphocholine(POPC). Solid-state ³¹P and ²H NMR experiments were carriedout to study the behavior of POPC bilayers in the presence ofthe hydrophobic peptide PLB at temperatures ranging from 30°Cto 60°C. The PLB peptide concentration varied from 0 mol% to 6 mol % with respect to POPC. Solid-state ³¹P NMR spectroscopyis a valuable technique to study the different phases formedby phospholipid membranes. ³¹P NMR results suggest that thetransmembrane protein phospholamban is incorporated successfullyinto the bilayer and the effects are observed in the lipid lamellarphase. Simulations of the ³¹P NMR spectra were carried out toreveal the formation of different vesicle sizes upon PLB insertion.The bilayer vesicles fragmented into smaller sizes by increasingthe concentration of PLB with respect to POPC. Finally, molecularorder parameters (S_CD) were calculated by performing ²H solid-stateNMR studies on deuterated POPC (sn-1 chain) phospholipid bilayerswhen the PLB peptide was inserted into the membrane.

INTRODUCTION

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

Methods for understanding interactions between proteins andlipids are essential for elucidating biological structure-functionrelationships. Peptide-lipid interactions can affect both proteinand bilayer structure (Bloom et al., 1991; Lemmon and Engelman,1994a; Watts, 1993). Previous studies have suggested that theseinteractions can serve several regulatory roles such as controllingthe membrane-association of lytic peptides, modulating membrane-proteinactivity, promoting peptide aggregation, segregating proteinswithin the membrane, determining protein sorting during secretionrecognition (Arora and Tamm, 2001; Dempsey et al., 1986; Lemmonand Engelman, 1994b; Watts, 1981). Three typical models of biologicalmembranes are planar lipid bilayers, vesicles (liposomes) andmonolayers. According to Singer-Nicholson's model of a cellmembrane, a lipid bilayer resembles a biomembrane closer thana monolayer (Singer and Nicolson, 1972). Liposomes or phospholipiddispersions are commonly used to study membrane structure uponpeptide insertion (Epand, 1998; Liu et al., 2001). In an aqueoussolution, phospholipids self-assemble to form lipid bilayersrather than micelles. The reason is that phosphatidylcholineshave two acyl chains that are more or less parallel to one another.The overall shape of a phospholipid molecule is approximatelyrectangular, so these molecules are too bulky to fit in theinterior of micelles. The well-defined synthetic membranes areused as model systems to mimic the properties of biologicalmembranes. Interestingly, the lipid bilayer in biological membranesis generally in the liquid-crystalline phase where the axisof symmetry of the acyl chain motion is perpendicular to theplane formed by the polar headgroup.

High-resolution NMR techniques are now routinely employed tostudy the structure of complex macromolecules in solution (Brunneret al., 2000; Cavagnero et al., 1999; Ottiger and Bax, 1999;Vold et al., 1997). An alternative approach to solution structuralstudies of membrane macromolecules is the determination of theirstructural and dynamic properties using solid-state NMR spectroscopy.Solid-state NMR spectroscopy has been widely used to study thestructure and dynamics of peptides, including those that associatewith membranes or with biomineral surfaces (Barre et al., 2003;Cross, 1997; Long et al., 1998, 2001; Marassi et al., 1999;Marassi and Opella, 1998; Marcotte et al., 2003; Nakazawa andAsakura, 2003; Nicholson and Cross, 1989; Shaw et al., 2000;Watts, 1998). For membrane-bound peptides, solid-state NMR spectroscopyhas the ability to probe lipid bilayers in the presence of apeptide, which can be poised in a biologically relevant liquid-crystallinestate. Membrane proteins reconstituted into synthetic phospholipidbilayers simulate the biological membrane better than detergentmicelles such as sodium dodecyl sulfate (Morrow and Grant, 2000;Rigby et al., 1996; Sharpe et al., 2002a,b).

Phospholamban (PLB) is a small transmembrane peptide (52 aminoacids) that interacts with the Ca²⁺-ATPase pump and lowers itsaffinity for Ca²⁺ (Simmerman et al., 1986, 1996; Simmerman andJones, 1998; Stokes, 1997; Yao et al., 2001). It consists ofthree domains: residues 1–20 (hydrophilic cytoplasmicdomain), residues 21–30 (hinge segment), and residues31–52 (hydrophobic ${alpha}$ -helical membrane-spanning region).Because of its biological importance and its relatively smallsize, PLB has been the benchmark used in many theoretical andexperimental studies of membrane protein structure and assemblies.Fujii and co-workers elucidated the complete PLB primary structureby amino acid sequencing (Fujii et al., 1987). They establishedthat the molecular mass of the PLB monomer was 6082 Da and determinedthat PLB is a pentamer consisting of five identical subunits.

Determining the structure of PLB and its interactions with thelipid bilayer is central for understanding its regulatory role(Mascioni et al., 2002a,b; Ying et al., 2000). The transmembranesegment of PLB (24–52) has been synthesized using solid-phasepeptide synthesis and purified according to the modified methodreported recently by our group (Tiburu et al., 2003). In thepresent study, the transmembrane domain of PLB (24–52)was incorporated into phospholipid bilayers prepared from 1-palmitoyl-2-oleoyl-sn-glycero-phosphatidylcholine(POPC). Solid-state NMR spectroscopy has been used to monitorthe interactions between the lipid bilayers and PLB, by exploitingthe ³¹P nuclei as a natural spin reporter on the headgroup ofPOPC. Solid-state ³¹P NMR spectroscopy is a valuable techniqueto study the different phases formed by model phospholipid membranes(Cullis and de Kruijff, 1979; Seelig, 1978). The ³¹P NMR lineshapes have distinct characteristics for different lipid phasessuch as the gel and liquid crystalline lamellar phases, theinverted hexagonal phase, and isotropic phases such as smallvesicles or micelles (Smith and Ekiel, 1984). The low chainmelting point of POPC makes it possible to examine PLB in membranesat a physiologically relevant temperature utilizing solid-stateNMR spectroscopy. In the present paper, we are focusing on threemain points: 1), lipid-peptide interactions of PLB incorporatedinto POPC bilayers utilizing ³¹P NMR spectroscopy; 2), perturbationsof the phospholipid bilayers using POPC-d₃₁ as a NMR probe;and 3), the effects of various concentrations of PLB and temperatureon the dynamic properties of the phospholipid bilayers.

MATERIALS AND METHODS

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

Materials
9-Fluorenylmethoxycarbonyl (Fmoc)-amino acids and other chemicalsfor peptide synthesis were purchased from Applied Biosystems(Foster City, CA). POPC and POPC-d₃₁ were purchased from AvantiPolar Lipids (Alabaster, AL). Prior to use, phospholipids weredissolved in chloroform and stored at -20°C. Chloroform,hexafluoro-2-propanol, formic acid, and 2,2,2 trifluoroethanol(TFE) were purchased from Sigma-Aldrich (Milwaukee, WI). Highperformance liquid chromatography-grade acetonitrile and 2-propanolwere obtained from Pharmco (Brookfield, CT) and were filteredthrough a 0.22-µm nylon membrane before use. Water waspurified using a Nanopure reverse osmosis system (Millipore,Bedford, MA). N-[2-hydroxyethyl]piperazine-N'-2-ethane sulfonicacid (HEPES) and EDTA were obtained from Sigma-Aldrich.

Synthesis and purification of PLB
PLB was synthesized according to the recently published procedure(Tiburu et al., 2003). In brief, PLB was synthesized using modifiedFmoc-based solid-phase methods with an ABI 433A peptide synthesizer(Applied Biosystems, Foster City, CA). The sequence of the synthesizedtransmembrane segment of PLB (24–52) is ARQNLQNLFINFCLILICLLLICIIVMLL.The crude peptide was purified on an Amersham Pharmacia BiotechAKTA explorer 10S high performance liquid chromatograph controlledby Unicorn (version 3) system software. A C₄ semipreparativepolymer supported column (259VHP82215) was acquired from GraceVydac (Hesperia, CA). Columns were equilibrated with 95% solventA and 5% solvent B. Solvent A consisted of H₂O and solvent Bwas 38% MeCN, 57% IPA, and 5% H₂O. Elution of the peptide wasachieved with a linear gradient to a final solvent compositionof 93% solvent B. The purified peptide was lyophilized and characterizedby matrix-assisted laser desorption ionization time-of-flightmass spectrometry.

NMR sample preparation
The POPC-rich bilayer samples, containing various mol % of peptideto phospholipid, were prepared following a slightly modifiedprotocol given by Rigby and co-workers. (1996). POPC (76 mg)and PLB were dissolved in CHCl₃ and TFE, respectively, and addedto a 12 x 75-mm test tube. The solvents were removed under asteady stream of N₂ gas for $~$ 15–20 min. The test tube wasplaced in a vacuum dessicator overnight to remove any residualsolvents. The peptide/lipid mixture was resuspended in 190 µLHEPES buffer (5 mM EDTA, 20 mM NaCl, and 30 mM HEPES, pH 7.0)by heating in a water bath at 50°C along with slight frequentsample agitation to avoid frothing the mixture. After all thephospholipids were fully dissolved, the sample was transferredto a NMR sample tube. POPC-d₃₁ (4 mg) was added to the sampleswhen conducting the ²H NMR experiments.

NMR spectroscopy
³¹P NMR spectra were recorded on a Bruker Avance 500-MHz solid-stateNMR spectrometer operating at 202.4 MHz using a Bruker doubleresonance 5-mm round coil static probe (Bruker, Billerica, MA).The ³¹P NMR spectra were recorded with ¹H decoupling using a4-µs ${pi}$ /2 pulse for ³¹P and a 5-s recycle delay. For the³¹P NMR spectra 1024 scans were taken and the free inductiondecay was processed using 100 Hz of line broadening. The spectralwidth was set to 150 ppm. ²H NMR spectra were recorded on thesame NMR spectrometer operating at 76.77 MHz using the same5-mm static round coil NMR probe. The quadrupolar echo pulsesequence was employed using quadrature detection with completephase cycling of the pulse pairs (Davis et al., 1976). The 90°pulse length was 3 µs, the interpulse delay was 20 µs,the recycle delay was 0.4 s, and the spectral width was setto 100 kHz. A total of 12,288 transients was averaged for eachspectrum and processed using 200 Hz line broadening. The samplewas held at the desired temperature for 10 min prior to signalacquisition.

NMR data analysis
Simulation of ³¹P NMR spectra was carried out using the softwareprogram called DMFIT (Massiot et al., 2002). This program permitsthe fitting or modeling of experimental 1D and 2D spectra toa sum of lines or contributions characterized by their correspondingNMR parameters. The spectral fittings were conducted using aminimum number of species. Static chemical shift anisotropyspectral patterns were considered for all the species. Lorentzianbroadening was used for all simulations.

Powder-type ²H NMR spectra of multilamellar dispersions of POPC-d₃₁were numerically deconvoluted (dePaked) using the algorithmof McCabe and Wassall (1995, 1997). The spectra were deconvolutedsuch that the bilayer normal was perpendicular with respectto the direction of the static magnetic field. The quadrupolarsplittings were directly measured from the dePaked spectra andconverted into order parameters according to the following expression(Dave et al., 2003; Huster et al., 2002):

where is the quadrupolar splitting for a deuteron attached to the ith carbon, e²qQ/h is the quadrupolar splittingconstant (168 kHz for deuterons in C-²H bonds), and is the chain order parameter for a deuteron attachedto the ith carbon of the acyl chain of POPC. The ²H nuclei attachedto the terminal methyl carbons were assigned carbon number 15.The remaining ²H assignments were made in decreasing order alongthe phospholipid acyl chain. Thus, the corresponding order parametersfor the individual C-D methylene groups and the terminal methylgroups of the acyl chains were directly evaluated from the quadrupolesplittings of the dePaked ²H NMR spectra. The ²H peaks in theNMR spectra were assigned based upon the dynamic propertiesof the individual CD₃ and CD₂ groups. The quadrupole splittingsof the CD₃ methyl groups at the end of the acyl chains are thesmallest and closest to 0 kHz because they rotate at the fastestfrequency. The next smallest splitting was assigned to the ²Hattached to C-14 and so forth along the acyl chain. The quadrupolesplittings for the deuterons in the plateau region were estimatedby integration of the last broad peak according to the literature(Huster et al., 1998). The order parameters calculated for theCD₃ quadrupole splitting were multiplied by 3 according to theliterature (Dufourc et al., 1984; Stockson et al., 1976).

RESULTS AND DISCUSSION

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

³¹P NMR study of PLB incorporated into POPC bilayer
³¹P NMR spectroscopic measurements were performed to determinethe nature of the various lamellar and nonlamellar phase transitionsexhibited by the transmembrane segment of PLB incorporated intoPOPC phospholipid bilayers. The static ³¹P NMR spectra of thePOPC phospholipid bilayer with and without 1 mol % of the hydrophobicsegment of PLB are shown in Fig. 1, A and B, respectively. The³¹P powder-pattern NMR spectra were recorded at temperaturesranging from 30°C to 60°C. The motionally averaged powder-patternspectra are characteristic of phospholipid bilayers in the liquidcrystalline phase (L) and are expected for POPC at a temperaturewell above its chain melting transition temperature of -3°C(Seelig, 1978). The spectra in the absence and in the presenceof 1 mol % PLB showed a similar powder lineshape, both with ${eta}$ = 0 (axial symmetry). The spectra indicate that the lipid bilayersremain in the L phase even after addition of 1 mol % phospholambanwith respect to POPC, and do not form isotropic or inverse hexagonalphases with high curvatures. In the L phase, a POPC bilayerhas been determined to have a hydrophobic thickness of $~$ 27 Å(Harzer and Bechinger, 2000; Nezil and Bloom, 1992). The entirethickness of the POPC phospholipid bilayer is $~$ 50–54 Å(Huber et al., 2002). If the hydrophobic region of PLB (24–52)is 100% ${alpha}$ -helical then it would be $~$ 43 Å in length (Joneset al., 1994). This indicates that the POPC bilayer is a closematch in thickness to the transmembrane segment of PLB and hydrophobicmismatch is not a serious problem under these conditions. Thepeptide is incorporated into the bilayer without distortingthe lipid structure. Hydrophobic mismatch for model peptidesKK(LA)₁₅KK (45 Å hydrophobic length) have been studiedin detail using ³¹P and ¹⁵N NMR spectroscopy (Harzer and Bechinger,2000). Those results clearly suggest that the POPC bilayer isa perfect match for hydrophobic peptides with a 36- to 45-Ålength. A dioleoyl phosphophatidyl choline (DOPC) bilayer hasbeen used previously for incorporation of AFA-PLB into a mechanicallyoriented membrane system (Mascioni et al., 2002a). The ³¹P NMRspectra of POPC samples containing no PLB and with 1 mol % PLBwere found to possess chemical shift anisotropy (CSA; in thispaper, CSA is ${sigma}$ _ll - ${sigma}$ ) widths of 44 ppm and 41 ppm, respectively(Seelig, 1978; Sharpe et al., 2002a,b). A somewhat smaller ( $~$ 3ppm) ³¹P CSA width is detected for the membrane-bound samplein our study as seen from the lineshape simulations. Similarly,in both cases by increasing the sample temperature, the CSAwidth decreases, indicating that the molecular motion in thephospholipid bilayer increases with temperature.

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FIGURE 1 ³¹P NMR spectra of POPC phospholipid bilayers investigated as a function of temperature. (A) In the absence of PLB, spectra are shown for pure POPC bilayers. (B) ³¹P spectra are shown for the POPC bilayer in the presence of 1 mol % PLB with respect to POPC. The solid-line spectra represent the experimental results and the dotted-line spectra represent best-fit simulated spectra corresponding to the experimental spectra.

Higher concentrations of PLB were also incorporated into POPCbilayers to probe the peptide-lipid interactions. Fig. 2, Aand B, show the experimental and simulated ³¹P NMR spectra ofPOPC bilayer samples containing 4 mol % PLB with respect tophospholipid. Similarly, Fig. 3, A and B, represent the experimentaland simulated ³¹P NMR spectra of POPC bilayer samples containing6 mol % PLB with respect to phospholipid. The results clearlyindicate that PLB interacts with the headgroups of the POPCbilayer. This study was performed at temperatures ranging from30°C to 60°C. The unoriented multilamellar liposomesamples containing 0–6 mol % peptide were all found toproduce ³¹P NMR powder-pattern spectra representing POPC inthe L phase even at higher temperatures (60°C). The membraneremains in the lamellar phase upon binding of PLB even at thehighest peptide concentration (6 mol %) studied. The overallCSA spectral width is $~$ 3 ppm smaller when compared to the purePOPC membrane. This can be attributed to a faster rotation ofthe lipids when the membrane-associated PLB peptide partiallydisrupts the hydrogen bonding network between the lipid headgroups.At higher concentrations of PLB, the spectra represent superpositions of the different lamellar phases. Previously, thepresence of two different anisotropic or lamellar phases wasobserved in the spectral simulations of ³¹P NMR spectra of cardiotoxinincorporated into 1,2-dimyristoyl-sn-glycero-3-phosphocholinebilayers (Auger, 1997

). Also, Strandberg and co-workers reportedthe presence of three different lamellar phases upon incorporationof the peptide KK(LA)₈KK into DOPC bilayers utilizing ³¹P NMRspectroscopy (Strandberg et al., 2001

). To fully understandthe peptide-lipid interactions from ³¹P NMR, spectral simulationshave been carried out as explained in the materials and methodsection (Figs. 2 B and 3 B). It is important to note here thatthe ³¹P chemical shift of phosphodiester, such as is found inmembrane lipids, depends upon the molecular motions and orientationof the group with respect to the magnetic field of the spectrometer(Smith and Ekiel, 1984

). The orientation of the headgroup dependsupon the chemistry, hydration, hydrogen bonding, and chargeinteractions of each phospholipid headgroup. ³¹P NMR spectraare very sensitive to the rate of motions of lipids in the liquidcrystalline phase, which usually have motional rates in thefast-limit region. Burnell and co-workers were able to simulateexperimental spectra of DOPC vesicles of different sizes atvarious temperatures and viscosities of the medium (Burnellet al., 1980

). The general results from these studies indicatethat the spectral lineshape and CSA width are dependent uponthe size of the vesicles. The CSA spectral width decreases withdecreasing vesicle size, and isotropic lines are observed forvery small vesicles. The formation of micelles or small vesiclesby fragmentation of the bilayers and the observation of differentphases has been observed previously on other membrane proteinsutilizing ³¹P NMR spectra obtained from the phospholipids ofmechanically oriented bilayers (Hori et al., 1999

; Hallock etal., 2003

; Henzler Wildman et al., 2003

). The structural resultsgleaned from both aligned and unoriented solid-state NMR samplesare important because the morphological membrane structure isdifferent for the two methods.

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FIGURE 2 ³¹P NMR spectra of POPC phospholipid bilayers in the presence of 4 mol % PLB with respect to POPC investigated as a function of temperature. (A) Experimental spectra. (B) The dotted-line spectra represent the simulated bilayer species having different vesicle sizes possessing different CSA widths. The solid-line spectra are the sum of the dotted-line spectra and represent the best-fit simulated spectra corresponding to the experimental spectra.

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FIGURE 3 ³¹P NMR spectra of POPC phospholipid bilayers in the presence of 6 mol % PLB with respect to the phospholipid POPC bilayers investigated as a function of temperature. (A) Experimental spectra. (B) The dotted-line spectra represent the simulated bilayer species having different vesicle sizes possessing different CSA widths. The solid-line spectra are the sum of the dotted-line spectra and represent the best-fit simulated spectra corresponding to the experimental spectra.

The ³¹P NMR in Figs. 2 A and 3 A at higher concentrations ofPLB clearly indicates that the presence of an isotropic peakand a shallow high-field shoulder (near to ${sigma}$ ). The spectral simulationsreveal the presence of different species of POPC bilayers (Figs.2 B and 3 B). The interpretation of the ³¹P NMR spectra withthe isotropic components is not certain (Pinheiro et al., 1997

).In some studies, they have been attributed to vesicular or micellarstructures on or within the bilayers, possibly associated withdifferent phases (Cullis and de Kruijff, 1979

; de Kruijff andCullis, 1980

). Others have attributed them to the presence ofsmaller diameter vesicles induced upon protein binding (Pinheiroand Watts, 1994a

). Alternatively, the lineshapes may arisefrom a different ³¹P species, which undergoes molecular motionthat yields isotropic chemical shift transitions. Despite thenonbilayer spectral component being broader from lipid-peptidecomplexes when compared to peptide-free bilayers, there is noindication of a well-defined hexagonal H_II phase. The spectralsimulation of ³¹P NMR lineshape clearly indicates the presenceof two different lamellar phases and one isotropic phase. Thepresence of two lamellar phases having different CSA width valuesalso indicates the presence of multilamellar vesicles (MLVs)of different sizes forming different microdomains. The presenceof an isotropic component indicates the existence of very smallsize vesicles like micelles. Interestingly, spectral simulationssuggest the presence of different species at higher PLB concentrations,when compared to 1 mol % PLB in which case only one speciesis present (Fig. 1). The ³¹P NMR spectral lineshapes clearlyindicate (Figs. 1–3) that the phospholipid bilayers aredisrupted by increasing the concentration of PLB. The presenceof one species having a similar large CSA width (41 ppm) wasobserved for the control and 1 mol % PLB sample and suggeststhe presence of large size MLVs. The smaller CSA width obtainedfor the other lamellar phases when 4% and 6 mol % PLB was addedto the POPC bilayer suggests the presence of smaller size vesicles(Burnell et al., 1980

). The large size vesicles can be fragmentedto form microdomains composed of small size vesicles. The diameterof the vesicles can be calculated from the CSA width for differentMLVs species (Burnell et al., 1980

). At 1 mol % PLB with respectto POPC, larger MLVs with an approximate diameter of 25,000Å are formed. When 4 mol % PLB was embedded into the bilayerstwo different size vesicles were formed with approximate diametersof 20,000 and 1500 Å. Additionally, the isotropic componentssuggest the presence of very small vesicles having diameters<1000 Å. Analysis of the 6 mol % PLB/POPC data indicatesthat large size vesicles fragmented and formed the componentspossessing vesicles with a diameter of $~$ 10,000 and $~$ 2500 Å,and one isotropic component with a diameter <1000 Å.The contributions of each component were calculated by integratingthe area of the individual species and comparing it with theentire CSA width of the experimental spectrum. These resultsindicate that when 4 mol % PLB was incorporated into POPC, contributionsfrom component I (large CSA width), component II (small CSAwidth), and component III (isotropic species) are $~$ 82%, $~$ 17%,and $~$ 1%, respectively, at 30°C. In addition to that, contributionsfrom component I decreased from 82% to 67% and contributionsfrom component II and component III increased from 17% to 26%and 1% to 7%, respectively, when the temperature was increasedfrom 30°C to 60°C. Interestingly, at 30°C the samplecontaining 6 mol % PLB/POPC was found to have contributionsfrom component I, component II, and component III of $~$ 67%, $~$ 25%,and $~$ 8%, respectively. Contributions from component I decreasedfrom 67% to 39% and increased for component II from 25% to 44%and for component III from 8% to 17% by increasing the temperaturefrom 30°C to 60°C. A comparison of Figs. 2 and 3 indicatesthat the contribution from the anisotropic phases having smallerCSA widths increases as more PLB is incorporated into the phospholipidbilayers. One can see clearly from Figs. 2 and 3 that upon increasingthe temperature the contributions from the different specieschange. At higher temperatures, molecular motions increase andsmall vesicles rotate faster. Also, lateral diffusion influencesthe ³¹P NMR lineshape of phospholipid bilayer (Burnell et al.,1980

; Cullis and de Kruijff, 1979

; Smith and Ekiel, 1984

). Anotherpossibility is that by increasing the amount of PLB incorporatedinto the POPC bilayer, the lateral diffusion rate of the lipidsat higher temperature increases, resulting in a decrease inthe CSA width of the ³¹P NMR spectra.

²H NMR study of PLB incorporated into POPC bilayer
The effect of PLB on the order and dynamics of the acyl chainsof the POPC bilayer have been studied using POPC-d₃₁ (deuteratedpalmitoyl acyl chain). The ²H NMR spectra of a dispersion ofPOPC-d₃₁ in the absence and in the presence of PLB at 35°Care shown in Fig. 4. Several conclusions can be immediatelydrawn from the ²H NMR lineshapes in Fig. 4. First, the spectraare characteristic of axially symmetric motions of the phospholipidsabout the bilayer normal and the spectra consist mostly of overlappingdoublet resonances that result from the different CD₂ segmentsof the acyl chain. The central doublet corresponds to the terminalCD₃ group. Secondly, the spectral width is a measure of thefluidity of the lipid bilayer. The range observed in the POPC/POPC-d₃₁is typical for acyl chains in a liquid-crystalline bilayer (Lafleuret al., 1989; Seelig and Seelig, 1974; Seelig and Niederberger,1974). In Fig. 4, the spectral width of POPC-d₃₁ marginallydecreases by increasing the PLB concentrations when comparedto the control spectrum of pure POPC/POPC-d₃₁. The marginaldecrease in the spectral width suggests that the presence ofthe PLB peptide disorders the acyl chains to some extent forall the different PLB/POPC concentrations. It also reveals thatthe POPC bilayer is still in the liquid-crystalline L phase.This supports our ³¹P NMR results as discussed earlier. Thespectral resolution deteriorates as the concentration of PLBincreases, manifested by the disappearance of the sharp edgesof the peaks. This suggests intermediate-timescale motions ofthe lipids induced by the PLB peptide. The changes in the spectralresolution of the ²H NMR spectra confirm that PLB interactswith the acyl chains of the lipid bilayers. Interesting featuresof the ²H NMR spectra are the appearance of an isotropic peakin the presence of PLB the intensity of which increases withthe amount of PLB. This indicates that the large vesicles arefragmented into smaller size vesicles by increasing the amountof PLB in the POPC bilayers. These results agree with our ³¹PNMR data.

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FIGURE 4 ²H NMR powder spectra of PLB at various concentrations incorporated into POPC/POPC-d₃₁ phospholipid bilayers at 35°C. 5.55 mol % POPC-d₃₁ was doped into the POPC sample. The concentration of PLB with respect to POPC is noted on the right side of each spectrum.

Fig. 5 shows the ²H NMR spectra of POPC-d₃₁ samples in the presence(4 mol %, dotted line) and in the absence (pure POPC/POPC-d₃₁bilayers, solid line) of PLB obtained over a temperature rangingfrom 30°C to 60°C. The shape of the ²H NMR spectra ofthe control POPC/POPC-d₃₁ is a typical ²H phospholipid bilayerlineshape (L phase), and looks very similar to those previouslyreported (Huber et al., 2002

; Lafleur et al., 1989

; Nezil andBloom, 1992

). As the temperature is raised, the spectra retaintheir overall lineshape in both cases with and without PLB.The spectral features become narrower due to increased mobilityby raising the temperature. The ²H NMR spectra with and without4 mol % PLB did not undergo any substantial changes in the spectralbreadth or quadrupolar splitting. Interestingly, the isotropiccomponent observed by the addition of 4 mol % PLB indicatesthe formation of small vesicles due to the fragmentation oflarge vesicles throughout the temperature range from 30°Cto 60°C. The intensity of the isotropic peak increases asthe temperature increases, indicating an increase in the rapidtumbling of small vesicles and/or an increase in lateral diffusionof the phospholipids (Davis, 1979

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FIGURE 5 Temperature-dependent ²H NMR spectra of PLB incorporated into POPC/POPC-d₃₁ phospholipid bilayers. The solid-line spectra represent POPC/POPC-d₃₁ sample prepared in the absence of PLB, whereas the dotted-line spectra represent samples prepared with 4 mol % PLB with respect to POPC. The temperature at which each spectrum was taken is noted on the right side of that spectrum.

The smoothed segmental C-D bond order parameters (S_CD) werecalculated by dePaking the powder spectra represented in Fig. 5for the POPC-d₃₁ as a function of temperature (Fig. 6). TheS_CD order parameters depend upon several averaging modes providedby intramolecular, intermolecular, and collective motions (Sandersand Schwonek, 1992

; Seelig and Seelig, 1974

; Seelig and Niederberger,1974

). The segmental S_CD order parameter describes local orientationor dynamic perturbations of the C-D bond vector from its standardstate due to perturbations of the POPC phospholipid conformationsor dynamics as a result of the addition of PLB. The magnitudeof the order parameters (S_CD $~$ 0.20–0.30) indicates thatthe phospholipid bilayers are in the liquid-crystalline phase(Huster et al., 1998

; Lafleur et al., 1989

). A characteristicprofile of decreasing order parameters with increasing distancefrom the glycerol backbone was obtained both for the pure bilayerand for the PLB-bound bilayer. These values are comparable withthe results previously determined using labeled POPC by NMR,and also recently calculated by using molecular dynamic simulations(Huber et al., 2002

; Seelig and Seelig, 1974

). The data indicatesthat there is more disorder and motion in the center and atthe end of the acyl chain when compared to the headgroup regionin the presence of PLB. Interestingly, the order parameter profileobtained from the sample in the presence of PLB (4 mol %) closelyresembles the order parameter profile of pure POPC bilayers.This indicates that the POPC bilayer acyl chains are not significantlyperturbed by the addition of PLB at these concentrations. Also,the order parameter profiles indicate (for both cases) thatby increasing the temperature, the S_CD values decrease. Thisis due to a combination of the increase in the mobility of theacyl chains, rapid tumbling of vesicles, and possible increasesin lateral diffusion of the POPC phospholipids.

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FIGURE 6 Temperature-dependent smoothed acyl chain (POPC-d₃₁) orientational order S_CD profiles calculated from the dePaked spectra of Fig. 5. (A) Pure POPC bilayer. (B) 4 mol % PLB embedded into the POPC bilayer.

	CONCLUSIONS

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

In the present study, the ³¹P NMR spectra indicated that thehydrophobic segment of phospholamban was incorporated successfullyinto the fully hydrated dispersed POPC phospholipid bilayers.The spectral simulations of ³¹P NMR spectra of samples containinghigher concentrations of PLB indicate the presence of differentsizes of vesicles. The large phospholipid bilayer vesicles fragmentedinto smaller vesicles by increasing the concentration of PLBwith respect to POPC. Interestingly, the contribution from smallervesicles increased as the temperature increased. The data indicatethat small vesicles are tumbling faster at higher temperatures.Another possibility is that by increasing the amount of PLBincorporated into the POPC bilayer, the lateral diffusion rateof the lipids increases at higher temperatures. In additionto the ³¹P NMR studies, ²H NMR spectroscopic studies were carriedout using POPC-d₃₁ to understand the lipid-peptide interactionsin the hydrophobic region of the phospholipid bilayers. Thedata suggest that smaller size vesicles are formed by the additionof 4 mol % PLB into the bilayers and support our ³¹P NMR spectralstudy. The segmental S_CD order parameter indicates that thereare no significant changes in the ordering of the acyl chainsof the phospholipid bilayers. It suggests that the incorporationof PLB into the POPC bilayers did not significantly perturbthe acyl chains of the phospholipid bilayers at these concentrations.In the present paper, solid-state NMR spectroscopic studieswere carried out to better understand the lipid-peptide interactionsfrom the membrane perspective utilizing unoriented POPC lipidbilayers. The unoriented phospholipid bilayer samples used inthe study with PLB can be used for a variety of magic anglespinning experiments such as REDOR (rotational-echo double-resonance).These experiments can reveal unique structural information onPLB with respect to the membrane. Future solid-state NMR experimentsspecifically designed to investigate the spatial position andorientation of the PLB with respect to the membrane utilizingsite-specific ²H-labeled and ¹⁵N-labeled PLB samples mechanicallyaligned on glass plates are in progress.

ACKNOWLEDGEMENTS

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

This work was supported by an American Heart Association ScientistDevelopment grant (0130396N) and a National Institutes of Healthgrant (GM60259-01). The 500-MHz wide-bore NMR spectrometer wasobtained from a National Science Foundation grant (10116333).

Submitted on September 8, 2003; accepted for publication November 4, 2003.

REFERENCES

TOP
ABSTRACT
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MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
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