The Chemistry of Phospholipid Binding by the Saccharomyces cerevisiae Phosphatidylinositol Transfer Protein Sec14p as Determined by EPR Spectroscopy

doi:10.1074/jbc.M603054200

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The Chemistry of Phospholipid Binding by the Saccharomyces cerevisiae Phosphatidylinositol Transfer Protein Sec14p as Determined by EPR Spectroscopy^*

Tatyana I. Smirnova¹, Thomas G. Chadwick, Ryan MacArthur, Oleg Poluektov, Likai Song^¶, Margaret M. Ryan^||², Gabriel Schaaf^||²³, and Vytas A. Bankaitis^||⁴

From the Department of Chemistry, North Carolina State University, Raleigh, North Carolina 27695, Argonne National Laboratory, Argonne, Illinois 60439, ^¶Florida State University, Tallahassee, Florida 32310, and the ^||Department of Cell and Developmental Biology, Lineberger Comprehensive Cancer Center, University of North Carolina, Chapel Hill, North Carolina 27599-7090

Received for publication, March 30, 2006 , and in revised form, August 31, 2006.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The major yeast phosphatidylinositol/phosphatidylcholine transferprotein Sec14p is the founding member of a large eukaryoticprotein superfamily. Functional analyses indicate Sec14p integratesphospholipid metabolism with the membrane trafficking activityof yeast Golgi membranes. In this regard, the ability of Sec14pto rapidly exchange bound phospholipid with phospholipid monomersthat reside in stable membrane bilayers is considered to beimportant for Sec14p function in cells. How Sec14p-like proteinsbind phospholipids remains unclear. Herein, we describe theapplication of EPR spectroscopy to probe the local dynamicsand the electrostatic microenvironment of phosphatidylcholine(PtdCho) bound by Sec14p in a soluble protein-PtdCho complex.We demonstrate that PtdCho movement within the Sec14p bindingpocket is both anisotropic and highly restricted and that theC₅ region of the sn-2 acyl chain of bound PtdCho is highly shieldedfrom solvent, whereas the distal region of that same acyl chainis more accessible. Finally, high field EPR reports on a heterogeneouspolarity profile experienced by a phospholipid bound to Sec14p.Taken together, the data suggest a headgroup-out orientationof Sec14p-bound PtdCho. The data further suggest that the Sec14pphospholipid binding pocket provides a polarity gradient thatwe propose is a primary thermodynamic factor that powers theability of Sec14p to abstract a phospholipid from a membranebilayer.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Phosphatidylinositol transfer proteins (PITPs)⁵ represent asubset of a larger group of phospholipid transfer proteins thatare operationally defined by their ability to mobilize phospholipidsbetween membrane bilayers in vitro. PITPs catalyze such energy-independenttransfer of either phosphatidylinositol (PtdIns) or phosphatidylcholine(PtdCho) between membrane bilayers in vitro, with PtdIns representingthe preferred ligand in the transfer reactions (1, 2). PITPsthemselves are highly conserved across the eukaryotic kingdomand fall into two distinct classes based upon primary sequenceand structural fold (reviewed in Ref. 2). These two classesare defined as the Sec14p-like PITPs and the unrelated metazoanPITPs. Deficiencies in metazoan PITP functions are either cell-lethalin mammals or, in the case of PITP- ${alpha}$ isoform, result in neurodegenerative,glucose homeostatic, and intestinal malabsorbtion diseases inmice (3). Sec14p domain proteins are also of medical interest,since inherited disorders, such as vitamin E-responsive ataxia,ataxia/dystonia in the jittery mouse, etc., are associated withindividual defects in them (4, 5). Moreover, the developmentalswitch from yeast to mycelial growth modes, a morphogeneticprogram whose execution is essential for the pathogenesis ofdimorphic yeast, is also regulated by Sec14p isoforms (6, 7).The preponderance of evidence indicates that PITPs integratethe action of specific phospholipid metabolic reactions withregulation of specific membrane trafficking processes.

The largest and most widely distributed PITP class is representedby the Sec14p-like proteins, so named on the basis of the foundingmember of the family, the yeast Sec14p PITP. The Sec14p-likePITP class consists of nearly 300 members, and it is appropriateto consider this large group of proteins as the Sec14p superfamily(2). The Sec14p lipid binding domain is employed in a bindingstrategy for a diverse set of hydrophobic ligands (e.g. phospholipids,phosphoinositides, sterol precursors, retinal, and tocopherols)and can be expressed either as a free standing domain or asone that is integrated into multidomain modules. The simplebudding yeast S. cerevisiae expresses six Sec14ps, and thisprotein class is more highly expanded in higher eukaryotes (e.g.at least 31 members in Arabidopsis) (8).

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FIGURE 1.
Crystal structure of the S. cerevisiae Sec14p. The Sec14p fold (Protein Data Bank code 1AUA) (9) consists of 12 ${alpha}$ -helices, six $beta$ -strands, and eight 3₁₀-helices. An en face view of the molecule that reveals the hydrophobic phospholipid binding pocket is shown in ribbon diagram mode (A). The Sec14p crystal structure is of an apo-form bound to two molecules of $beta$ -octyl glucoside (shown in space fill mode). These two detergent molecules reside in the single large hydrophobic pocket of the protein, and the pocket is proposed to be gated by the A10/T4 helix (in black; helix labeled), which is posited to reside in an "open" conformation in the apo-Sec14p structure. B depicts a view of the Sec14p molecule from the top so that the dominant structural element of the back of the molecule (the string motif; labeled and in black) is revealed. The string motif stabilizes the Sec14p fold by wrapping behind the $beta$ -strand floor of the hydrophobic pocket.

The available Sec14p crystal structure for Sec14p identifiesa novel fold that forms a hydrophobic pocket of sufficient volumeto accommodate a single molecule of PtdIns or PtdCho (Fig. 1)(9). The crystallizing unit is an apo-Sec14p loaded with twomolecules of the detergent $beta$ -octyl glucoside. This particularstructure is interpreted to describe a transitional Sec14p conformerthat exists only transiently on the membrane surface as Sec14pundergoes phospholipid exchange. Although an understanding ofhow Sec14p functions at the molecular level is incomplete, thestructural model spawned several hypotheses regarding intramoleculardynamic aspects of Sec14p function (9). First, an unusual surfacehelix (A10/T4) is identified as an attractive candidate forthe structural element that "gates" the hydrophobic pocket (Fig. 1A).Second, a string motif that contains a series of four tightlywound 3₁₀ helices wraps up the Sec14p fold and is suggestedto play an important role in regulating conformational changesthat accompany the phospholipid exchange reaction (Fig. 1B).

How Sec14p actually binds its phospholipid substrates remainsan important and unanswered question. The available model providesconsiderable insight into how Sec14p might bind target membranesand individual phospholipids. With regard to substrate bindingin the soluble Sec14p-phospholipid complex, bound phospholipidis predicted to orient with the acyl-chains packed into thehydrophobic interior of the pocket, whereas the phospholipidheadgroup is disposed toward solvent. Although this hypothetical"headgroup-out" disposition of the bound phospholipid is bothan attractive and an intuitive one, solution of a phospholipid-boundSec14p structure is required to resolve this question, and nosuch information is yet available. Resolution of this issueis important, since it speaks to one of several potential mechanismsfor how Sec14p (and Sec14p-like proteins) may regulate phospholipidmetabolism. The uncertainty surrounding whether the intuitiveorientation of phospholipid within the Sec14p pocket is indeedthe correct one is emphasized by structural analyses of phospholipid-boundmetazoan PITPs. These proteins bind phospholipid substratesin the reverse "headgroup-in" orientation (10, 11).

In this report, we describe our application of EPR spectroscopyto probe the local dynamics and the electrostatic microenvironmentof a series of spin-labeled n-doxyl-PtdCho molecules incorporatedinto the Sec14p phospholipid binding pocket. We demonstratethat motion of PtdCho within the Sec14p binding pocket, whileanisotropic and highly restricted, nonetheless exhibits a progressiveincrease in the mobility of the sn-2 acyl chain as distancefrom the headgroup/backbone region increases. Moreover, we showthat the C₅ region of the sn-2 acyl chain is highly shieldedfrom solvent, whereas the distal region of the acyl chain isless so. Finally, we describe evidence for a polar protic microenvironmentat position C₅ of the sn-2 acyl chain that becomes increasinglyaprotic as one moves away from the headgroup/backbone regionof the bound phospholipid and returns to a more polar/proticenvironment at the distal end of the chain. These collectivedata are most consistent with a headgroup-out orientation ofSec14p-bound PtdCho and further indicate that the Sec14p phospholipidbinding pocket provides a hydrophobic matching to accommodatethe PtdCho molecule. We propose this polarity gradient is aprimary thermodynamic factor that drives the ability of Sec14pto abstract a phospholipid from a membrane bilayer.

EXPERIMENTAL PROCEDURES

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Expression and Purification of Sec14p—Recombinant His₆-Sec14pwas purified from Escherichia coli essentially as previouslydescribed (9). Briefly, Sec14p expression in E. coli strainKK2186 ( ${Delta}$ (lac-pro) supE thi strA sbcB-15 endA/F'(traD36 lacI^QlacZ ${Delta}$ 15)) was driven by a derivative of the pQE31 plasmid (Qiagen,Hilden, Germany) and induced with isopropyl $beta$ -thiogalactoside(1 mM final concentration). Bacterial cultures were incubatedfor an additional 5 h with shaking at 37 °C. Cells wereharvested by centrifugation, and the cell pellet was resuspendedin ice-cold lysis buffer (50 mM sodium phosphate, pH 7.1, 300mM NaCl, 1 mM NaN₃, 0.2 mM phenylmethylsulfonyl fluoride). Lysozymewas added, and the suspension was incubated at 25 °C foran additional 10 min. Cells were disrupted by collision with0.1-mm diameter glass beads in a cooled bead beater (BiospecProducts, Bartlesville, OK). Cell lysates were subsequentlyclarified by differential centrifugation series at 1000 x g,14,000 x g, and 100,000 x g, respectively. The clarified supernatantwas applied to Talon^TM Sepharose resin (Clontech), the resinwas washed extensively with lysis buffer, and bound proteinwas eluted with a linear imidazole gradient (0–200 mM)reconstituted in lysis buffer. Peak fractions were pooled anddialyzed extensively against lysis buffer at 4 °C, and asecond round of affinity purification and dialysis was subsequentlyperformed. Protein purity was monitored by SDS-PAGE and CoomassieBlue staining of gels. Sec14p purity exceeded 95%, and purifiedprotein exhibited robust PtdIns and PtdCho transfer activity.

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FIGURE 2.
Structure of lipids and selected spin probes used in this work: PtdCho (a), PtdIns (b), 5-doxyl-PtdCho (c), 10-doxyl-PtdCho (d), 16-doxyl-PtdCho (e).

Preparation of EPR Samples—Nitroxide-labeled PtdCho species,1-acyl-2-(n-(4,4-dimethyloxazolidine-N-oxyl)stearoyl)-sn-glycero-3-phosphocholine(n-doxyl-PtdCho), with the spin label positioned at n = 5, 7,10, 12, and 16, were purchased from Avanti%20Polar%20Lipids">AvantiPolar Lipids, Inc. (Alabaster, AL) (Fig. 2) as chloroform solutions.Organic solvents for calibrating high field EPR spectra forpolarity and hydrogen-bonding effects included methanol, isopropylalcohol, and hexane (Sigma). All solvents were analytical gradeor higher and were used as received. Nickel(II) ethylenediamine-N,N'-diaceticacid (NiEDDA) was synthesized as described (12). NiEDDA 200mM stock solution was prepared in lysis buffer. 5-Doxyl-stearicacid (5-doxyl-SA) was purchased from TCI America (Portland,OR). Solutions of 5-doxyl-SA were typically prepared at concentrations $≤$ 1 mM (i.e. below the critical micellar concentration). A solutionof 5-doxyl-PtdCho in isopropyl alcohol was prepared at 0.1 mMconcentration.

Preparation of n-Doxyl-PtdCho Dispersions and n-Doxyl-PtdChoBinding to Sec14p—Multilamellar aqueous dispersions ofn-doxyl-PtdCho (20% by weight) were prepared as described (13).Previous studies have shown that spin-labeled lipids form bilayerswhen dispersed in water and exhibit similar phase behavior asbiological lipids (14).

To load Sec14p with n-doxyl-PtdCho, a 95 µM protein solutionwas mixed with a small molar excess of 100% spin-labeled multilamellarliposomes and incubated at room temperature for at least 2 h.As an assay for completeness of binding, we monitored bindingof n-doxyl-PtdCho to Sec14p by X-band EPR until no further changesin the signal amplitude were observed. This assay relies onour observation that the EPR signal from an isolated spin labeltypically exhibits much narrower features and is easily distinguishedfrom EPR spectra originating from n-doxylPtdCho liposomes (see"Results").

EPR Spectroscopy and Spectral Analysis—Continuous wave(CW) X-band (9.0–9.5 GHz) EPR spectra were acquired witha Century Series Varian E-109 (Varian Associates, Palo Alto,CA) EPR spectrometer and digitized to 2000 data points/spectrum.Typical spectrometer settings were as follows: microwave power2 milliwatts, field modulation frequency 100 kHz, and amplitudeless than 1 G to avoid overmodulation. Specific ranges of magneticfield scans are indicated in the figures. Variable temperatureEPR spectra were obtained using a nitrogen flow system connectedto a Varian variable temperature controller. Sample temperaturewas measured with a VWR International (West Chester, PA) digitalthermometer equipped with a stainless steel microprobe positionedin the cavity just above the sample. The VWR thermometer hasa resolution of 0.001 °C and accuracy of ±0.05 °C.In all experiments, temperature was controlled better than ±0.5°C.

High field (HF) EPR spectra were acquired with a 130 GHz EPRspectrometer constructed and installed in the Argonne NationalLaboratory (Argonne, IL). Field-swept echo-detected EPR spectrafrom spin-labeled samples were recorded at a temperature of25 K using a two-pulse sequence. Typically, ${pi}$ /2 pulses of 50ns in length were separated by a 350-ns delay, and the repetitionrate was set to 500 Hz. For detecting low temperature rigidlimit HF EPR spectra, we employed an echo-detected field-sweptmode over the conventional continuous wave scheme for severalreasons. First, the pulse detection eliminates signals originatingfrom spin-labeled n-doxyl-PtdCho bilayers (i.e. phospholipidsaggregated in a solution and not bound to Sec14p), because spinsof the former molecules have much shorter phase memory T₂ relaxationtime due to strong magnetic interactions with the neighboringspins. Second, low temperature echo-detected HF EPR spectrado not have microwave phase distortions, allowing for more accurateline shape and g-factor analysis.

For HF EPR, spin-labeled samples were drawn by capillary actioninto clear fused quartz tubes (inner diameter = 0.5 mm, outerdiameter = 0.6 mm; VitroCom, Mountain Lakes, NJ), sealed witha Critoseal clay (purchased from Fisher), and loaded into precooledcryostat at 25 K. Temperature of the EPR resonator and the samplewas controlled by an ITC-4 temperature controller coupled toa flow cryostat (all supplied by Oxford Instruments, Concord,MA).

Saturation recovery (SR) pulsed EPR experiments were conductedat 4 °C with a Bruker Biospin (Billerica, MA) X-band ElexSys680 EPR spectrometer installed at the National High MagneticField Laboratory (Tallahassee, FL). The SR measurements wereperformed using a 0.16-µs pump pulse and an amplifieroutput of 10 watts. Shot repetition time was 204 µs. EachSR curve was digitized to 1024 points. Data were acquired atthe field position corresponding to the maximum EPR intensity(m_I = 0 hydrogen hyperfine transition). Reference signal wasacquired at the 50-G shift in the lower field. Data on NiEDDAaccessibility to 5-doxyl-SA in a water/ethanol mixture wereprovided by Dr. J. Widomska (National Biomedical EPR Center,Milwaukee, WI).

Lorentzian line broadening induced by NiEDDA was measured fromCW X-band spectra using a one-parameter model (13, 15, 16).In brief, first derivative EPR spectra measured in the presenceof NiEDDA were least squares fitted using the Levenberg-Marquardtalgorithm to a convolution of the corresponding experimentalspectra recorded in the absence of paramagnetic relaxant anda Lorentzian broadening function. A modification of this approachfor elucidating very small broadening effects has been described(17).

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Binding of n-Doxyl-PtdCho to Sec14p—Binding of n-doxyl-PtdChoto Sec14p was monitored from changes in EPR spectra collectedat room temperature. Fig. 3A (dots) shows a typical room temperatureEPR signal obtained for 5-doxyl-PtdCho liposomes. For all n-doxyl-PtdChospecies studied, the signal appeared as a single line of $~$ 25–27G peak-to-peak width. Such a spectrum is characteristic of strongdipole-dipole and exchange interactions.

The single line EPR spectrum of spin-labeled lipids is wellmodeled by a Lorentzian function as illustrated for 5-doxyl-PtdChoin Fig. 3A; least squares simulations are shown as a solid linethat very closely follows the experimental spectrum. The spectrumin Fig. 3A also demonstrates that the EPR signals from nonaggregatedn-doxyl-PtdCho (i.e. n-doxyl-PtdCho resident in the aqueousbuffer) are too weak to be detected under these conditions.This is expected, because the critical micelle concentrationfor n-doxyl-PtdCho is in the nanomolar range, resulting in aconcentration of n-doxyl-PtdCho monomers in aqueous buffer thatis well below the typical sensitivity of X-band EPR spectrometers.

When Sec14p loads with a phospholipid from a membrane bilayer,the bound phospholipid becomes encapsulated in the protein cavity.Such a loading event effectively eliminates spin-spin interactionsfor the bound n-doxyl-PtdCho and produces significant line shapechanges. Fig. 3B (solid line) depicts a typical EPR spectrumobserved in experiments where Sec14p was mixed with multilamellar5-doxyl-PtdCho bilayers and allowed to equilibrate for $~$ 2 h.A sharp decrease in spin-spin interactions was observed forSec14p-bound 5-doxyl-PtdCho as reported by the line narrowing.This line narrowing results in a significant ( $~$ 6-fold) increasein the peak-to-peak amplitude of the corresponding EPR spectrumas compared with the initial signal from liposomal 5-doxyl-PtdCho.The presence of the signal from aggregated lipids is particularlynoticeable from broad wings that extend far away from characteristicfeatures (i.e. outside the dashed lines in Fig. 3B). Thus, thesignal from Sec14p-bound 5-doxyl-PtdCho dominates the firstderivative EPR spectrum observed in CW experiments, therebysimplifying initial analyses of local spin label dynamics. Intime domain experiments, such as saturation recovery and echo-detectedfield-swept HF EPR, little if any contribution from the liposomal5-doxyl-PtdCho is recorded, because the latter spin specieshave much shorter electronic relaxation times. However, foraccurate line shape least squares simulation analyses, the contributionfrom the remaining liposomal 5-doxyl-PtdCho (dashed line) issubtracted from the experimental spectrum (Fig. 3B, solid line),yielding the Sec14p-bound 5-doxyl-PtdCho spectrum (Fig. 3C).In this particular experiment, the fraction of liposomal 5-doxyl-PtdChomolecules was determined to be $~$ 30%.

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FIGURE 3.
Room temperature X-band CW EPR spectra from 5-doxyl-PtdCho. A, in a form of multilamellar lipid dispersion (field modulation amplitude 8G) (B, solid line) after mixing with 95 µM Sec14p in $~$ 1:1 molar ratio. Least squares fit of the spectrum (A) to a Lorentzian function is shown as a dashed line (B). C, signal from 5-doxyl-PtdCho incorporated into the Sec14p binding pocket obtained by the spectral subtraction.

Local Dynamics of n-Doxyl-PtdCho Incorporated into the Sec14pPhospholipid Binding Pocket—The data described above demonstratethat Sec14p loads with n-doxyl-PtdCho and that the bound n-doxyl-PtdChobecomes sequestered within the protein cavity. Since CW EPRspectra of spin-labeled phospholipids are sensitive to rotationalmotion of the nitroxide moiety, this method was used to investigatethe flexibility of the n-doxyl-PtdCho acyl chain within theSec14p lipid binding pocket. A series of room temperature (22°C) CW X-band spectra from n-doxyl-PtdCho (where n = 5,7, 10, 12, and 16) bound to Sec14p are shown in Fig. 4. Forall label positions analyzed, the contribution of liposomaln-doxyl-PtdCho registered only as a broad line most readilyobserved at the wings. This component was subtracted from experimentalspectra and will not be discussed further. Instead, we focuson the dominant EPR spectrum that originates from n-doxyl-PtdChosequestered within the Sec14p cavity.

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FIGURE 4.
Room temperature X-band CW EPR spectra from Sec14p-bound n-doxyl-PtdCho. Spectra are corrected for the background signal as illustrated in Fig. 2 and are intensity-normalized using double integration.

All EPR spectra depicted in Fig. 4 report an intermediate toslow motional regime and anisotropic rotation of the nitroxidespin label. The absence of any abnormal broadening and/or substantialdrop in intensity of these spectra indicative of spin-spin interactionsis consistent with a Sec14p molecule loading with a single n-doxyl-PtdChomolecule. A particularly informative parameter of such spectrais the peak-to-peak width ${Delta}$ H_p-p (m_I = 0) of the central nitrogenhyperfine component (where m_I = 0 is the nitrogen spin quantumnumber). When tumbling of a spin label falls into an intermediateto slow motional regime, this width is approximately proportionalto the rotational correlation time ${tau}$ _c. In studies of local dynamicsof protein side chains, an inverse of this width Formula

is typically reported as a "mobility" parameter(18). This parameter reliably estimates mobility of spin-labeledamino acid side chains in proteins, and a smaller mobility parameterindicates slower rotation and a longer rotational correlationtime ${tau}$ _c. Other useful parameters for characterizing rotationaltumbling of a nitroxide are the effective hyperfine splittingconstants A_out and A_in as defined in Fig. 4. A plot of the mobilityparameter, Formula

, as well as A_outand A_in, all indicate a progressive increase in spin label localmobility as the nitroxide label is moved toward the headgroup-distalend of the sn-2 acyl chain from position C₅ to C₁₂ (Fig. 5).At position C₁₆, however, motion of the label becomes more restricted,very much like at position C₅. We used the definition of McConnelland Hubbell to calculate the effective order parameter (S^eff)to describe the anisotropy of spin label motion (19, 20),

Formula (Eq. 1)
where A_|| = A_out (i.e.a half of the outer hyperfine splitting), and A is calculatedfrom A_in, a half of the inner hyperfine splitting expressedin gauss,

Formula (Eq. 2)

Formula (Eq. 3)

Formula (Eq. 4)
where A₀ is the isotropic nitrogen hyperfinecoupling constant, and ${Delta}$ A is the maximum extent of the axialnitrogen hyperfine anisotropy (21, 22). Although the valuesof ${Delta}$ A and A₀ vary by a few percent with the position of the labelalong the sn-2 acyl chain of Sec14p-bound n-doxyl-PtdCho, wefound it convenient to fix A₀ and ${Delta}$ A for all n-doxyl-PtdCho isomersto those values observed for 5-doxyl-PtdCho in isopropyl alcohol.In doing so, we introduced less than 3% error into the S^effcalculations. Effective order parameters S^eff calculated fromroom temperature X-band EPR spectra of Sec14p-bound n-doxyl-PtdChoare reported in Fig. 6 and are compared with S^eff values measuredfor n-doxyl-PtdCho in either a fluid dimyristoyl-PtdCho membranebilayer environment (T = 27 °C) or in a crystalline bilayerenvironment (T = 5 °C).

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FIGURE 5.
Empirical motional characteristics of nitroxide spin label as determined from room temperature T = 22 °C X-band CW EPR spectra of n-doxyl-PtdCho bound to Sec14p as function of the label position along the sn-2 acyl chain. A, A_out; B, A_in; C, mobility parameter, Formula

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FIGURE 6.
Effective order parameters S^eff calculated from X-band CW EPR spectra as a function of the label position. Filled circles, n-doxyl-PtdCho bound to Sec14p (T = 27 °C); open circles, S^eff for n-doxyl-PtdCho in dimyristoyl-PtdCho bilayers in a crystalline phase (T = 5 °C); open squares, S^eff for n-doxyl-PtdCho in dimyristoyl-PtdCho bilayers in fluid phase (T = 27 °C)

Substantial alterations in the label dynamic and order parametersare recorded as a function of the spin label position alongthe sn-2 acyl chain. Qualitative analyses of EPR spectra forSec14p-bound 5-doxyl-PtdCho indicate a highly restricted "slowmotional" regime that corresponds to ${tau}$ _c ${approx}$ 6–10 ns. For thisposition, the mobility parameter is the lowest ( Formula

), whereas the order parameter is the highest (S^eff= 0.72). For 7-doxyl-PtdCho, the mobility parameter increasesto 0.22G^–1, whereas S^eff decreases to 0.66. The outerhyperfine splitting A_out parameter decreases to 28 G, whereasA_in remains essentially the same. Such changes indicate fasterand less anisotropic local tumbling of the label that is consistentwith an increased local flexibility of the sn-2 acyl chain atC₇ relative to C₅. For 10-doxyl-PtdCho, the mobility parameterremains essentially the same, but A_out reduces to 25.15 G, andthe order parameter decreases to S^eff = 0.56. This indicatesreduced anisotropy of motion. For 12-doxyl-PtdCho, anisotropyof motion is diminished even further, and the nitroxide tumblingbecomes even faster as reported by the increased mobility parameter.

These collective data indicate an increase in sn-2 acyl chainrotational flexibility with increased distance from the headgroup/backbone-proximalregion of the Sec14p-bound PtdCho molecule and support a modelwhere Sec14p engages bound PtdCho most tightly at the backbone-headgroupand backbone-proximal regions of the phospholipid molecule.The data obtained for the series of n-doxyl-PtdCho moleculeswhere the nitroxide is positioned at and between C₅ and C₁₂are consistent with this hypothesis. The spectrum for 16-doxyl-PtdChois defined by the outer peaks separated by A_out = 30.27 G andhas an order parameter S^eff = 0.71. Those values report a verystrong immobilization of the nitroxide label and compare favorablywith parameters measured for 5-doxyl-PtdCho. The abrupt changein the mobility trend suggests that the tail of the lipid isstacked against the "floor" of the protein cavity. It is alsopossible that Sec14p is capable of forming hydrogen bond contactswith the somewhat hydrophilic nitroxide group of 16-doxyl-PtdCho.

PtdCho Is Strongly Immobilized in the Sec14p Phospholipid BindingPocket—Although a progressive increase in chain mobilityin the direction from the lipid head to the tail up to positionC₁₂ is clear from the EPR spectra described above, variabletemperature EPR experiments demonstrate that the local motionof the Sec14p-bound PtdCho sn-2 acyl chain remains highly restricted(Fig. 7). At all temperatures, all X-band EPR spectra for n-doxyl-PtdChomolecules labeled at positions C₅, C₇, and C₁₀ report a singlecomponent. Analyses of these spectra indicate a gradual decreasein the spectral anisotropy and an increase in mobility parameter, Formula , with increased temperature.

The activation energies associated with these dynamic processeswere calculated by plotting EPR spectral parameters as a functionof temperature in the Arrhenius coordinates (Fig. 8). For 5-doxyl-and 7-doxyl-PtdCho molecules, the slopes of the linear regressionswere essentially the same (–1.48 x 10³ K^–1 and –1.47x 10³ K^–1, respectively) yielding an activation energyof E_a = 12.3 kJ mol^–1. For 10-doxyl-PtdCho, however, theslope changes to –0.85 x 10³ K^–1 (E_a = 7.1 kJ mol^–1),indicating that the molecular interactions responsible for thebinding interface between bound PtdCho and Sec14p differ alongthe sn-2 acyl chain. Specifically, the effective potential barrierin the vicinity of the headgroup/backbone-proximal region ofthe Sec14p-bound PtdCho is greater than for the distal regionsof the sn-2 acyl chain.

Pulse Saturation EPR Analysis of Accessibility of Sec14p-boundn-Doxyl-PtdCho to a Soluble Broadening Agent—To probehow PtdCho is oriented within the Sec14p binding pocket, wemeasured the accessibility of the nitroxide spin label in aseries of Sec14p-bound n-doxyl-PtdCho molecules to water-solubleparamagnetic broadening reagent (NiEDDA). An analogous approachhas proven to be informative in determination of local proteinfolds and transmembrane protein structure (23–32) andfor mapping structural elements of membrane and peripheral proteins(25, 26). Moreover, the accessibility parameters of proteinside chains measured by EPR agree well with those computed fromcrystal structures (23, 24).

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FIGURE 7.
Variable temperature intensity-normalized experimental 9.5 GHz CW EPR spectra from 5-doxyl-PtdCho bound to Sec14p.

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FIGURE 8.
Temperature dependence of the mobility parameter for n-doxyl-PtdCho bound to Sec14p plotted in Arrhenius coordinates. Open circles, 5-doxyl-PtdCho; filled circles, 7-doxyl-PtdCho; filled squares, 10-doxyl-PtdCho. Best fit to the linear regression is shown as dashed lines.

The accessibility parameter is proportional to the Heisenbergexchange frequency (W_ex) of a nitroxide label with a broadeningagent that is freely diffusing in a solution. For the broadeningagent employed, the electronic spin-lattice relaxation timeis much shorter than that of a nitroxide, and the Heisenbergspin exchange is the predominant spin-spin inter action thataffects both spin label electronic relaxation times (T₁ andT₂).

Initially, molecular accessibility of the sn-2 acyl chain ofSec14p-bound n-doxyl-PtdCho was accessed in pulsed SR EPR experimentsto measure spin label electronic T₁_e directly in the absenceand presence of NiEDDA (50 mM). The amplitude of SR EPR signalsobserved for the central (m_I = 0) nitrogen hyperfine componentin the absence (I) and the presence (I^relaxant) of a paramagneticrelaxant can be described as follows,

Formula (Eq. 5)

Formula (Eq. 6)
where R₁_e and Formula are the corresponding electronic spin-lattice relaxation rates. The difference inthe relaxation rates R₁_e and Formula is proportional to the local concentration of the relaxant,

Formula (Eq. 7)
where the relaxivityconstant ${chi}$ is in turn proportional to the relative translationaldiffusion rate (D), which is the sum of translational diffusionrates of the spin label and the relaxant (D^SL and D^relaxant,respectively). Other contributing factors are the efficiency( ${rho}$ ) of a given collision to produce additional relaxation ofthe nitroxide spin and the collision distance r,

Formula 8 (Eq. 8)
The difference in relaxationrates ( ${Delta}$ R) for a given relaxant is a time-domain analogue ofthe accessibility parameter ${Pi}$ derived from CW EPR experiments(13, 33, 34).

Under the experimental conditions employed herein, the rotationalcorrelation time ${tau}$ _c of the spin label falls within the 1–10ns range, whereas the typical nuclear relaxation time for nitroxidesis $~$ 100 ns (34). Thus, recovery of the signal due to such fastprocesses is complete within EPR detection dead time and doesnot contribute to the SR EPR signal. Similarly, n-doxyl-PtdChomolecules remaining in an aggregated form (i.e. not associatedwith Sec14p) and therefore experiencing strong spin-spin interactionsexhibit electronic spin label relaxation rates that are muchfaster than those recorded for n-doxyl-PtdCho molecules loadedinto the Sec14p phospholipid binding cavity. Consequently, signalsfrom these irrelevant sources do not contribute to the observedSR signal.

For solvent-exposed nitroxide labels, the exchange rate (W_ex)with NiEDDA clamped at a concentration of 50 mM is expectedto be W_ex ${approx}$ 10⁵ s^–1, whereas the electronic relaxationrate R₁_e is $~$ 10⁶ s^–1. Therefore, for a single-componentEPR spectrum, one expects to observe a monoexponential SR EPRsignal. Experimental SR curves recorded in the absence and presenceof NiEDDA were fitted with a single or a double exponentialfunction. Fig. 9 shows the first 4-µs profile of a typicalSR EPR signal measured for air-equilibrated samples of Sec14p-bound5-doxyl-PtdCho with and without NiEDDA challenge. Since mechanismsof electronic relaxation through Heisenberg spin exchange forparamagnetic oxygen and NiEDDA are statistically independentand are not cross-correlated, the effect of oxygen is additiveand included in R₁_e. Both curves are well modeled by a singleexponential function, confirming that SR EPR signals from anyaggregated 5-doxyl-PtdCho still present in this sample are invisiblein the pulse saturation EPR experiment. SR EPR relaxation dataare summarized in Table 1. For Sec14p-bound 5-doxyl-PtdCho,the electronic relaxation rates in the absence and presenceof 50 mM NiEDDA were very similar (1.10 ± 0.01 and 1.14± 0.02 MHz, respectively). These data indicate that theC₅ position of the sn-2 acyl chain of Sec14p-bound 5-doxyl-PtdChois essentially inaccessible to NiEDDA.

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TABLE 1
Accessibility of lipid-labeled sites as measured in saturation recovery EPR experiments

Concentration of NiEDDA in each experiment was 50 mM unless otherwise specified. The ${chi}$ ' values are corrected ${chi}$ values when viscosity is taken into consideration. ${Delta}$ R_1e and ${chi}$ values for shielded and unshielded MTSL-labeled sites challenged with NiEDDA were reported elsewhere (36, 37). Accessibility of the each specified nitroxide spin label is calculated as the ratio of ${chi}$ / ${chi}$ ' x 100%, as indicated.

For 16-doxyl-PtdCho, the relaxation rate has changed from R₁_e= 0.41 MHz in the absence of relaxant to Formula 8

, corresponding to an increase in relaxation rateby ${Delta}$ r = 1.37 MHz in the presence of 50 mM NiEDDA (i.e. by 0.027MHz/mM NiEDDA).

To evaluate to what degree binding to Sec14p shields n-doxyl-PtdChofrom collision with the hydrophilic NiEDDA complex, we measuredthe relaxivity parameter ${chi}$ for an unshielded (i.e. unbound) lipid.To overcome problems posed by the insolubility of n-doxyl-PtdChoin water, we utilized a structurally similar compound, 5-doxyl-stearicacid (5-doxyl-SA), dissolved in a 50%/50% (v/v) water-ethanolmixture as a reporter. In the presence of 20 mM NiEDDA, ${chi}$ was0.15 MHz/mM. Corrections for the differences in relative translationaldiffusion rate of 5-doxyl-SA and the relaxant were evaluatedusing a simple hydrodynamic model for D = kT/6 ${pi}$ ${eta}$ r, where ${eta}$ isthe viscosity of the solution and r is the hydrodynamic radiusof the molecule. In these simplified calculations, we assumethe encounter partners are spherical in shape. For the spinlabel bound to the protein, the nitroxide translational diffusioncoefficient becomes that of the protein itself and is negligiblecompared with D^relaxant. Thus, we can assume that (D^SL + D^relaxant)= D^relaxant in Equation 8. The collision distance r remainsthe same, since NiEDDA and a nitroxide, but not the proteinitself, are the colliding species. For 5-doxyl-SA and NiEDDA,the hydrodynamic radii are taken to be approximately the same,resulting in (D^SL + D^relaxant) = 2D^relaxant. Assuming that thecollision efficiency ${rho}$ does not vary with solvent, the relationshipbetween the relaxivity ${chi}$ ' observed for spin-labeled protein inan aqueous solution of viscosity ${eta}$ ' and the relaxivity ${chi}$ '' foran unbound label in a water-ethanol mixture of viscosity ${eta}$ ''is ${chi}$ '/ ${chi}$ '' = ${eta}$ ''/2 ${eta}$ '. Adjusting for the differences in viscositiesof the solutions (35), the ratio ${chi}$ '/ ${chi}$ '' is estimated to be $~$ 1.43.Based on this calculation, we estimate the relaxivity for anunshielded doxyl label bound to protein to be 0.22 MHz/mM NiEDDA.The accessibility to the specific protein site is calculatedas a ratio of the experimentally observed relaxivity to therelaxivity of the model unshielded site (0.22 MHz/mM NiEDDA).For Sec14p-bound 5-doxyl-PtdCho, the relaxant accessibilityis $~$ 0.4%, whereas for 16-doxyl-PtdCho, it is $~$ 13%.

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FIGURE 9.
First 4 µs of saturation recovery signal from 5-doxyl-PtdCho bound to Sec14p in the absence and in the presence of 50 mM NiEDDA at T = 4 °C. Best fit to the single exponential growth is shown as a solid line.

Comparisons of the effects of NiEDDA on the electronic relaxationof Sec14p-bound n-doxyl-PtdCho with those reported for unshielded,solvent-exposed labeled sites are informative. For solvent-exposedside chains of water-soluble proteins labeled with 1-oxyl-2,2,5,5-tetramethyl-3-pyrroline-3-methyl(MTSL), ${Delta}$ R is typically about 0.13–0.22 MHz/mM NiEDDA (36).Although the effectiveness of collisions between NiEDDA andthe n-doxyl-PtdCho spin label could differ from collisions ofNiEDDA with MTSL, the largest ${chi}$ value we observed (0.027 MHz/mMfor 16-doxyl-PtdCho) is still substantially lower than thosemeasured for water-exposed protein residues. We have also comparedour ${chi}$ values with those of transmembrane helices. For example,Robinson and co-workers (37) investigated the effects of NiEDDAon electronic relaxation of an MTSL-labeled transmembrane WALPpeptide incorporated into 1,2-dioleoyl-sn-glycero-3-phosphocholinebilayers. For a spin-labeled site located $~$ 10 Å from thecenter of the bilayer, ${chi}$ was measured to be 0.0006 MHz/mM, whereasat a site positioned closer to the membrane surface (18 Åfrom the bilayer center), ${chi}$ was recorded at 0.0016 MHz/mM. The ${chi}$ = 0.0008 MHz·mM^–1 value we measure for Sec14p-bound5-doxyl-PtdCho falls between these two values.

Collectively, the ${Delta}$ R value obtained for Sec14p-bound 5-doxyl-PtdChoby pulse saturation EPR methods indicates that C₅ of the sn-2acyl chain exhibits a solvent molecular inaccessibility comparablewith that of a deeply buried protein site. However, experimentswith Sec14p-bound 16-doxyl-PtdCho reveal that ${Delta}$ R for the C₁₆position of that acyl chain is measurably higher, suggestingthat C₁₆ is a partially shielded site with a solvent accessibility $~$ 13% that of an unshielded label.

CW EPR Analysis of Accessibility of Sec14p-bound n-Doxyl-PtdChoto NiEDDA—To complement the SR EPR data, we employed CWEPR to evaluate accessibility of spin label to NiEDDA in a seriesof n-doxyl-PtdCho molecules loaded into Sec14p. Collisions betweena label and a paramagnetic relaxant shorten the nitroxide electronicT₂ relaxation time. This effect is observed as Lorentzian broadeningthat is uniform across the experimental CW EPR spectrum. Detailedinvestigations of nitroxide-NiEDDA spin-spin interactions insolutions of various viscosities ( ${eta}$ ) demonstrate that collisionsare in a "strong" exchange limit and that Lorentzian broadeninginduced by NiEDDA is a linear function of 1/ ${eta}$ up to NiEDDA concentrationsof 100 mM (25). The contribution to the line width from dipolarspin-spin interactions is negligible.

The data collected from CW EPR measurements of the peak-to-peakLorentzian broadening in the presence and absence of NiEDDA(50 mM) are summarized in Table 2. Lorentzian broadening wasextracted using a one-parameter convolution algorithm (15).The broadening was determined to be only 90 mG (measured aspeak-to-peak) for Sec14p-bound 5-doxyl-PtdCho and 10-doxyl-PtdCho.This value is at the detection limit of the experiment. Thisminiscule effect is consistent with the very low accessibilityof the C₅ position of the sn-2 acyl chain to NiEDDA as determinedby the SR measurements described above. The broadening observedfor 12 and 16-doxyl-PtdCho is 100 and 310 mG, respectively.Fig. 10 shows the result of the fit for 16-doxyl-PtdCho. Theabsence of any substantial residual of the fits confirms thatthe shortening of the electronic relaxation time recorded bySR EPR upon NiEDDA challenge primarily reports exchange interactionsrather than changes in the dynamics of Sec14p-bound n-doxyl-PtdChoor significant conformational changes within Sec14p.

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TABLE 2
Accessibility of lipid-labeled sites as measured in X-band CW EPR experiments

Concentration of NiEDDA is 50 mM in all experiments. ${delta}$ ${Delta}$ H_p-p for 5-doxyl-SA was measured in a water/EtOH solution (1:1, v/v). This measurement represents a model "unshielded" nitroxide label. The Formula 8 value corrected for viscosity of the water/EtOH solution is also given. Accessibility of the each specified nitroxide spin label is calculated as the ratio of , as indicated.

In a control experiment, the Lorentzian broadening for 5-doxyl-SA(1 mM) in a water/ethanol solution was measured as a functionof NiEDDA concentration. The relaxivity was determined to be19 mG/mM. When corrected for viscosity of the water/methanolmixture and for the mutual diffusion coefficient (as discussedabove for SR EPR experiments), the broadening for an unprotectedprotein site exposed to aqueous NiEDDA was calculated to be27 mG/mM. From this calibration, the molecular accessibilityof the spin label for Sec14p-bound 16-doxyl-PtdCho is estimatedto be $~$ 23% that of an unshielded site (Table 2).

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FIGURE 10.
Experimental 9 GHz CW EPR spectrum from 16-doxyl-PtdCho bound to Sec14p in the presence of 50 mM NiEDDA (trace A, solid line) is superimposed with the result of the fit using a Lorentzian broadening model (trace B, dashed line). Residual of the fit (experiment fit) is shown as trace C.

In summary, the CW line width broadening accessibility dataare in qualitative agreement with the SR EPR data. Both methodscharacterize the C₅ position of the sn-2 acyl chain of Sec14p-boundPtdCho as essentially inaccessible to hydrophilic NiEDDA andassign the C₁₆ position of that acyl chain as a shielded, butpartially accessible, site. The difference in the absolute numbersreported by SR EPR and CW measurements could be due to substantialnonhomogeneity of the labeled sites. The CW line width broadeningmethod is sensitive only to the states with relatively highaccessibility. The SR method, especially when very high concentrationsof a broadening agent are used, can report on highly protectedprotein sites. We speculate that those two methods may be sensingconformational fluctuations of the Sec14p-PtdCho complex insolution, and that a probe positioned at the end of the sn-2acyl chain is especially sensitive to such fluctuations.

Characterization of Local Polarity of the Sec14p Lipid BindingPocket—The local polarity within the Sec14p phospholipid-bindingpocket was evaluated by measuring both the electronic g-matrixand nitrogen hyperfine coupling tensor A parameters of Sec14p-boundn-doxyl-PtdCho species. High spectral resolution achieved byHF EPR permits very accurate determination of electronic g-matrixcomponents from the powder pattern spectra and evaluation ofpolarity and hydrogen bond effects in a variety of biologicalsystems (38–45). Fig. 11 depicts a series of 130 GHz echo-detectedspectra of Sec14p-bound n-doxyl-PtdCho. Systematic changes,primarily in magnetic field positions of the g_x (low field)spectral component, are clearly apparent. As the nitroxide labelis moved from position C₅ to C₁₂ of the sn-2 acyl chain, thiscomponent progressively shifts to a lower field. This correspondsto an increase in the magnitude of g_x. The z-component of thenitrogen hyperfine coupling tensor (A_z) was measured from acharacteristic splitting in the high field region of the spectra.The largest values for A_z were recorded for Sec14p-bound 5-doxyl-and 7-doxyl-PtdCho, and those values were equivalent (A_z = 34.7± 0.25 G). Those data indicate a similar polarity andproticity of the microenvironments at positions C₅ and C₇ ofthe sn-2 acyl chain of Sec14p-bound 5-doxyl- and 7-doxyl-PtdChospecies. Values for A_z decreased to 33.85 ± 0.25 G forSec14p-bound 10-doxyl-PtdCho and increased to 34.15 ±0.25 and 35.17 ± 0.25 G for 12-doxyl-PtdCho and 16-doxyl-PtdCho,respectively. These data show small, but clearly measurable,shifts to a less polar and more aprotic environment as the spinlabel is positioned further down the sn-2 acyl chain from theheadgroup/backbone region of Sec14p-bound PtdCho up to positionC₁₂ and return to a more polar, proctic environment at positionC₁₆.

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FIGURE 11.
Rigid limit 130 GHz echo-detected EPR spectra from n-doxyl-PtdCho bound to Sec14p at T = 25 K.

Fig. 12 shows the g_x component of electronic g-matrix for Sec14p-boundn-doxyl-PtdCho as a function of the position of the spin labelalong the sn-2 acyl chain. A systematic shift in the x-componentto lower field/higher g-factor is clearly observed as the spinlabel is positioned along the sn-2 acyl chain from C₅ towardC₁₂. This trend is broken at position C₁₆, for which the g_xcomponent shifts to higher field/lower g-factor. The observedshift indicates a transition from a polar and more protic environmentat C₅ to one that is less polar and more aprotic at C₁₂ andthen a return to a more polar and protic environment at positionC₁₆. Again, this is in agreement with our conclusions reachedfrom measurements of the nitrogen hyperfine coupling componentA_z. On the other hand, the g_y component was insensitive to spinlabel position. This is consistent with both theoretical andexperimental considerations that the y-component of electronicg-matrix is much less affected by solvent polarity than is thex-component (39–41).

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FIGURE 12.
Dependence of the g_x component on spin label chain position (n) for n-doxyl-PtdCho bound to Sec14p as measured from 130 GHz echo-detected EPR spectra. For purposes of calibration, the arrows show the g_x component for n-doxyl-PtdCho dispersed in hexane (A) and in methanol (B).

Polarity Reference Measurements—As a means for calibratingpolarity references for n-doxyl-PtdCho, we obtained 130 GHzspectra from 5-doxyl-PtdCho dispersed in methanol, isopropylalcohol, and hexane. Analysis of g_x and A_z magnetic parametersas a function of the label position n on the sn-2 acyl chainindicated that C₅ and C₁₆ were situated in the most polar proticenvironment. The local polarity gradually changes to less polarand more aprotic as the label is moved along the sn-2 acyl chainto C₁₂. From comparisons of 130 GHz EPR spectra of Sec14p-boundn-doxyl-PtdCho with those measured for 5-doxyl-PtdCho in theseorganic solvents, we find that the local electrostatic environmentof C₅ and C₇ approximates that of bulk isopropyl alcohol. Forcomparison, g_x for spin label in hexane is also shown (Fig. 12).

In principle, the observed shift might have two origins. Thefirst one is the effect of hydrogen bond formation, and thesecond is the effect of polar amino acid side chains locatedin the immediate vicinity of the label. Previous studies haveshown that the g_x shift is substantially higher in protic solventscapable of hydrogen bond formation than in aprotic solvents,even if the solvents have comparable dielectric constants (43).Theoretical analyses using density functional theory (DFT) calculationspredicted that formation of a single hydrogen bond would shiftthe g_x component by ${Delta}$ g_x =–4.4 x 10^–4 (42). In thisregard, we note that the magnitude of the shift observed forthe g_x component for Sec14p-bound 12-doxyl-PtdCho with respectto that for 16-doxyl-PtdCho is about –5.2 x 10^–4(i.e. a value very close to the theoretically predicted shiftdue to formation of a single hydrogen bond).

The polarity gradient we observe within the Sec14p phospholipid-bindingcavity suggests that C₅ of the sn-2 acyl chain is located ina relatively polar and protic protein environment, whereas theenvironment of the middle of the chain is nonpolar and aprotic.The distal end of the molecule (C₁₆), however, resides in morepolar, protic surroundings. These data are most consistent withthe bound phospholipid oriented in such a way that the headgroupregion is disposed toward solvent, whereas the acyl chains emanateinto the hydrophobic interior of the Sec14p phospholipid bindingpocket. When coupled with our demonstration of a low accessibilityfor C₅ to the water-soluble paramagnetic relaxant NiEDDA, wepropose the polarity of the Sec14p phospholipid-binding cavityreported by 5-doxyl-PtdCho is not the result of free solventpenetration into this region. Rather, we suggest that our dataare indicative of a propensity of the spin label positionedat C₅ to be engaged in hydrogen bonding with neighboring aminoacid residues.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

We describe herein the first spin-labeling EPR experiments toaccess local dynamics and the electrostatic microenvironmentof a PtdCho molecule sequestered within the Sec14p phospholipid-bindingpocket. We demonstrate that Sec14p loads effectively with PtdChospecies labeled with a doxyl moiety at various positions alongthe sn-2 acyl chain. Once bound, n-doxyl-PtdCho species exhibitassignable and informative CW EPR spectral profiles. Analysesof CW EPR spectra from an n-doxyl-PtdCho series demonstratethat mobility of the spin label increases in proportion to distancealong the sn-2 acyl chain from the headgroup/backbone regionof Sec14p-bound PtdCho and that this increase in mobility isaccompanied by a decrease in anisotropy of motion. These findingsindicate that Sec14p invests in tighter interactions with theheadgroup/backbone-proximal region of bound phospholipid, whereasinteractions with the distal regions of the acyl chains areless robust. The observed decrease in the mobility of the lipidtail can be due to contact with the cavity "floor." It alsocould indicate interaction of the somewhat polar nitroxide probewith the protein backbone by hydrogen bonding. Although a progressiveincrease in sn-2 acyl chain mobility is observed with distancefrom the headgroup/backbone region, the overall acyl chain mobilityof Sec14p-bound PtdCho remains anisotropic and strongly restricted.

Measurements of the paramagnetic relaxant accessibility to thelipid chain show that positions 5–12 are strongly shieldedfrom hydrophilic solute molecules. The distal acyl chain regionof bound phospholipid exhibits limited accessibility to hydrophilicparamagnetic broadening agents ( $~$ 23% of what would be normallyobserved for solvent-exposed protein residues). High field EPRexperiments also provided evidence for an electrostatic polaritygradient inside the lipid-binding pocket, suggesting a proticelectrostatic microenvironment at position C₅ of the sn-2 acylchain with an increasing aproticity as one moves toward theC₁₂ of the chain. The more polar, protic environment detectedfor the distal terminus of the sn-2 acyl chain is consistentwith higher NiEDDA accessibility or possible interaction withpolar protein residues through hydrogen bond formation. Thus,the Sec14p phospholipid-binding pocket provides a hydrophobicmatching to accommodate the PtdCho molecule, and the configurationof this electrostatic gradient is most consistent with a headgroup-outorientation of PtdCho within the Sec14p pocket. We propose thatthis gradient provides the driving thermodynamic force thatallows Sec14p to abstract a phospholipid from a membrane bilayer.

FOOTNOTES

^* The work at North Carolina State University was supported byNational Science Foundation Grant MCB-0451510 with partial supportfrom American Chemical Society Petroleum Research Fund Grant40771-G4 (both to T. I. S.). The work at Argonne National Laboratorywas supported by the United States Department of Energy, Officeof Basic Energy Sciences, Division of Chemical Sciences, Geosciences,and Biosciences, under Contract W-31-109-Eng-38. The NationalBiomedical EPR Center is supported by National Institutes ofHealth (NIH) Grant EB001980. The costs of publication of thisarticle were defrayed in part by the payment of page charges.This article must therefore be hereby marked "advertisement"in accordance with 18 U.S.C. Section 1734 solely to indicatethis fact.

² Supported by NIH Grant GM44530 (to V. A. B.).

³ Supported by a postdoctoral training grant from the DeutscheForschungsgemeinschaft.

¹ To whom correspondence may be addressed: Dept. of Chemistry, North Carolina State University, 2620 Yarborough Dr., Raleigh, NC 27695. Tel.: 919-513-4375; Fax: 919-513-7353; E-mail: Tatyana_Smirnova{at}ncsu.edu. ⁴ To whom correspondence may be addressed: Dept. of Cell & Developmental Biology, 108 Taylor Hall, University of North Carolina, Chapel Hill, NC 27599-7090. Tel.: 919-962-9870; Fax: 919-966-1856; E-mail: vytas{at}med.unc.edu.

⁵ The abbreviations used are: PITP, phosphatidylinositol transferprotein; PtdIns, 1,2-dioleoyl-sn-glycero-3-phosphoinositol (ammoniumsalt); 10-doxyl-PtdCho, 1-acyl-2-(10-(doxyl)stearoyl)-sn-glycero-3-phosphocholine;16-doxyl-PtdCho, 1-acyl-2-(16-(doxyl)stearoyl)-sn-glycero-3-phosphocholine.

ACKNOWLEDGMENTS

We thank Eric Ortlund for helpful discussions. We gratefullyacknowledge assistance with SR experiments from the NationalBiomedical EPR Center.

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ABSTRACT
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EXPERIMENTAL PROCEDURES
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DISCUSSION
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