Orientation and Pore-Forming Mechanism of a Scorpion Pore-Forming Peptide Bound to Magnetically Oriented Lipid Bilayers

doi:10.1529/biophysj.104.043513

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Orientation and Pore-Forming Mechanism of a Scorpion Pore-Forming Peptide Bound to Magnetically Oriented Lipid Bilayers

Kaoru Nomura^*, Gerardo Corzo^*, Terumi Nakajima^* and Takashi Iwashita^*

^* Suntory Institute for Bioorganic Research, Osaka 618-8503, Japan; and Institute of Biotechnology-Universidad Nacional Autónoma de México, Cuernavaca, Morelos 62210, Mexico

Correspondence: Address reprint requests to K. Nomura, E-mail:nomura{at}sunbor.or.jp.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

The orientation and pore-forming mechanisms of pandinin 2 (pin2),an antimicrobial peptide isolated from venom of the Africanscorpion Pandinus imperator, bound to magnetically orientedlipid bilayers were examined by ³¹P and ¹³C solid-state, and¹⁵N liquid-state NMR spectroscopy. ³¹P NMR measurements at varioustemperatures, under neutral and acidic conditions, showed thatmembrane lysis occurred only under acidic conditions, and attemperatures below the liquid crystal-gel phase transition ofthe lipid bilayers, after incubation for two days in the magnet.Differential scanning calorimetry measurements showed that pin2induced negative curvature strain in lipid bilayers. The ¹³Cchemical shift values of synthetic pin2 labeled at Gly³, Gly⁸,Leu¹², Phe¹⁷, or Ser¹⁸ under static or slow magic-angle spinningconditions, indicate that pin2 penetrates the membrane withits average helical axis perpendicular to the membrane surface.Furthermore, amide H-D exchange experiments of ¹⁵N-Ala⁴, Gly⁸,and Ala⁹ triply-labeled pin2 suggest that this peptide formsoligomers and confirms that the N-terminal region creates membranepores.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Antimicrobial peptides with ${alpha}$ -helical conformations are commonlyand broadly found in nature and often induce permeation of lipidmembranes (Maloy and Kari, 1995; Andreu and Rivas, 1998). Manyantimicrobial peptides have been classified as pore-formingpeptides such alamethicin, cecropin, PGLa, magainin, mellitin,and mastoparan. The pore-forming mechanisms of antimicrobialpeptides have been extensively studied and several mechanismsof pore formation have been proposed (Shai, 1999; Bechinger,1999). Alamethicin (North et al., 1995; Bak et al., 2001) insertsinto the membrane hydrophobic core and creates a pore by formingtransmembrane helical bundles. PGLa (Bechinger et al., 1998),cecropin A (Marassi et al., 1999), and ovispirin (Yamaguchiet al., 2001) are situated at the membrane surface and self-associate,in a "carpet-like" manner, onto the acidic phospholipid-richdomains of lipid bilayers. When a threshold concentration ofpeptide is reached, it permeates into the membrane by increasingthe positive curvature of the bilayer. Magainin 2 (Matsuzakiet al., 1998), mastoparan X (Matsuzaki et al., 1994, 1995a,b,1996a,b), and LL-37 (Henzler Wildman et al., 2003) form toroidalpores in lipid bilayers, where the inner monolayer is associatedwith the outer one via a phospholipid lining, and pores areformed by the lipid polar headgroups and the helix bundles orientedperpendicular to the membrane surface.

Pandinin 2 (Pin2, FWGALAKGALKLIPSLFSSFSKKD) is a pore-formingpeptide isolated from the crude venom of the African scorpionPandinus imperator (Corzo et al., 2001). This peptide showsantimicrobial activity against Gram-positive and Gram-negativebacteria, as well as strong hemolytic activity against sheeperythrocytes. Circular dichroism studies reveal an unorderedstructure in aqueous solution, with a more ordered ${alpha}$ -helicalstructure observed in a membrane-mimetic environment (DPC micelles).A high-resolution structure of pin2 in DPC micelles had beendetermined by solution NMR and showed a single ${alpha}$ -helical structureup to residues 18–19, with no significant kink aroundthe proline at position 14 (Corzo et al., 2001).

Since solid-state NMR methods do not need isotropic reorientation,they are frequently used to obtain structural information oninsoluble, amorphous or fibrous molecules and membrane-boundpeptides and proteins. When a sample is aligned with an appliedmagnetic field, the resulting signal shows an orientationaldependence on the NMR frequencies, which can provide valuableinformation concerning the orientation of membrane-bound peptidesin lipid bilayers, especially if the secondary structure alreadyis known (Cross and Opella, 1994; Marassi and Opella, 1998).Many oriented systems have been examined by solid-state NMR,where mechanically oriented systems with glass plates have beenused most frequently (Bechinger and Opella, 1991; Opella etal., 1999). Recently, a novel solid-state NMR method was reported(Naito et al., 2000; Toraya et al., 2004) which determines theconformation of peptides bound to highly hydrated, magneticallyoriented lipid bilayers, and hence more closely resembles physiologicalconditions. Therefore, we chose this method to examine the pin2binding and pore-formation mechanism in magnetically orientedphospholipid bilayers. We also investigated the pin2-lipid bilayerinteractions as a function of peptide concentration and pH,using ³¹P solid-sate NMR in a magnetically oriented system.N-H amide solvent exchange in DPC micelles was also studied,to examine the aqueous and hydrophobic pin2 environments.

EXPERIMENTAL

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Materials
Dimyristoyl-phosphatidylcholine (DMPC) and dimyristoyl-phosphatidylglycerol(DMPG) were purchased from Funakoshi (Tokyo, Japan). Dioleoyl-phosphatidylethanolamine(DOPE) and 1-palmitoyl-2-oleoylphosphatidylcholine (POPC) werepurchased from Avanti Polar Lipids (Alabaster, AL). Nonlabeledpin2, five kinds of site-specifically ¹³C=O labeled pin2; [1-¹³C]-Gly³,Gly⁸, Leu¹², Phe¹⁷, or Ser¹⁸, and ¹⁵N-Ala⁴, Gly⁸, Ala⁹ triply-labeledpin2 were synthesized on solid-phase using fluoren-9-ylmethoxycarbonyl(Fmoc) methodology on an Applied Biosystems (Foster City, CA)433A peptide synthesizer. Fmoc-Asp(ot-butyl)-Wang resin wasused to provide a free carboxyl at the C-terminus of pin2. Aftersynthesis, peptide deprotection, and cleavage from resin, thecrude peptides were dissolved in 40% acetonitrile solution andpurified by reverse-phase HPLC on a semipreparative C18 ODScolumn (10 x 250 mm, Nacalai Tesque, Kyoto, Japan). The massand the purity of the peptides were confirmed by matrix-assistedlaser-desorption ionization-time-flight-MS. Mastoparan was purchasedfrom Peptide Institute (Osaka, Japan).

Preparation of multilamellar vesicles
The membrane system was made of DMPC/DMPG (4:1) and co-solubilizedwith varying quantities of peptide in chloroform/methanol (8:1).After solvent evaporation under vacuum for two days, the lipidfilm was hydrated with Tris buffer containing 100 mM NaCl (pH= 7.6) at 40°C, vortex-mixed, and the pH adjusted with Trisbuffer. The suspension was freeze-thawed for 10 cycles and centrifuged.The supernatant was removed to adjust the water content to 85%(w/w), and the suspension transferred to NMR tubes sealed withglue to prevent dehydration. Five kinds of ¹³C=O labeled pin2were incubated for two days at 40°C in the magnet, and thenlyophilized, before ¹³C NMR experiments to determine the principalvalues of the carbonyl carbons, in the absence of any motion.

Solid-state NMR spectroscopy
All solid-state NMR spectra were acquired on a CMX Infinity300 spectrometer (Chemagnetics, Varian, Palo Alto, CA) operatingat a proton-resonance frequency of 300 MHz. ³¹P spectra wereacquired using a 5-µs single excitation pulse with 30kHz continuous wave (CW) ¹H decoupling during acquisition. Thedwell time was 50 µs and 256–512 transients wereaccumulated for each free induction decay with a 3-second delay.The ³¹P chemical shifts were referenced externally to 85% H₃PO₄(0 ppm). For ¹³C NMR measurements, 20,000–66,000 transientswere accumulated for each free induction decay with a 53-µsdwell time and a 3.7-second delay. For hydrated samples, spectrawere acquired using 4-µs excitation pulses with 30 kHzCW ¹H decoupling. The sample rotation speed was maintained at100 ±15 Hz for slow MAS experiments. For lyophilizedsamples, a cross-polarization (CP) experiment was performedwith a contact time of 2 ms, 40 kHz CP, and CW ¹H decouplingradio frequency. The ¹³C chemical shifts were externally referencedto the methine carbon of adamantine (29.5 ppm). ¹³C spectrawere processed using 50 Hz line broadening. Unless otherwisestated, samples were incubated for two days at 40°C beforedata acquisition.

Differential scanning calorimetry measurements
DOPE/POPC (6:1) and various amounts of pin2 were dissolved togetherin chloroform/methanol (2:1 v/v). The solvent was evaporatedunder a stream of dry nitrogen with last traces removed underhigh vacuum. The dried lipids were then dispersed in buffer,20 mM Tris-HCl, 100 mM NaCl, and 2 mM EDTA (pH = 7.6), by vigorousvortexing to produce a 50 mM phospholipid concentration. Differentialscanning calorimetry measurements were performed on a MicrocalMCS differential scanning calorimeter (Microcal, Amherst, MA)at a heating rate of 1°C/min. All scans were made afterfreezing the dispersion in dry ice. The data were analyzed usingsoftware provided by the manufacturer.

H-D exchange
N-H amide exchange experiments were performed on a Bruker DMX-750spectrometer (Karlsruhe, Germany) operating at a proton-resonancefrequency of 750 MHz. A series of two-dimensional ¹H-¹⁵N HSQCspectra at 40°C were taken at 5-min intervals after theaddition of D₂O, and were recorded with a recycle delay of 2s with two scans. The data were acquired with 64 points in the¹⁵N dimension corresponding to a 50-ppm spectral width, and2048 points in the ¹H dimension. A GARP decoupling sequence(Shaka et al., 1985) was applied during data acquisition. Thespectra were acquired using TPPI for quadrature detection (Marionand Wüthrich, 1983) in the t₁ dimension. The phase-shiftedsine bell functions were applied for both t₁ and t₂ dimensions.

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Concentration dependence of pin2–lipid bilayer interactions
To examine the effect of pin2 on lipid bilayers, the ³¹P NMRspectra of lipid bilayers in the presence and absence of pin2were measured under static conditions. Fig. 1 a shows the ³¹PNMR spectra of DMPC/DMPG (4:1) lipid bilayers at 40°C containingvarious amounts of pin2 at pH = 7.5. In the absence of pin2,an axially symmetric, motionally averaged powder pattern wasobserved where the ${delta}$ component is largest. This pattern indicatesthat the bilayers are magnetically aligned, with their normalperpendicular to the magnetic field (Dempsey and Watts, 1987)and the phospholipids are laterally diffused on the lipid bilayers.When pin2 was added to the bilayers in a peptide/lipid (P/L)molar ratio of 1:5000, there was an increase in the powder pattern-likenature of the ³¹P NMR spectrum. This indicated that the magneticalignment of the lipid bilayers was disturbed by the interactionof pin2 with the lipid headgroups even in the presence of suchsmall amounts of peptide. At P/L = 1:500–1:20, the lipidbilayer alignment showed greater disturbance, and at P/L = 1:200,the chemical shift of the DMPG signal was dramatically shifteddownfield. Fig. 1, b and c, show the ³¹P NMR spectra of DMPCand DMPG lipid bilayers, respectively, at 40°C and pH =7.5, with pin2 at P/L = 1:20. (Comparing Fig. 1, b and c, withFig. 1 a, we can unequivocally assign the two DMPC and DMPGsignals.) The DMPG shift at P/L = 1:20 could be due to the negativelycharged DMPG headgroup interacting with the positively chargedpin2 lysine, causing the phosphate group to tilt with respectto the axis of motional averaging, hence reducing the averagedchemical shift; i.e., the ${sigma}$ ₂₂( ${sigma}$ ₃₃) principal axis is parallelto the axis of motional averaging (Herzfeld et al., 1978; Schererand Seelig, 1989).

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FIGURE 1 Effect of pin2, at various concentrations, on the ³¹P NMR spectra of phospholipids in lipid bilayers composed of (a) DMPC/DMPG (4:1), (b) DMPC, and (c) DMPG at 40°C under neutral pH conditions. PC and PG indicate the signals of DMPC and DMPG, respectively.

DSC measurement
To elucidate the ability of pin2 to induce curvature strainon lipid bilayers, the effect of pin2 on the phase transitiontemperature T_H from lamellar liquid-crystalline phase (L) toinverted hexagonal phase (H_II) of DOPE was investigated. Fig. 2shows a series of DSC scans in the absence and presence ofpin2 in a DOPE/POPC (6:1) lipid mixture. T_H in the absence ofpin2 was 39°C and higher pin2 content resulted in lowerT_H values, implying that pin2 induces negative curvature strainin lipid bilayers (Hallock et al., 2002

). All DSC scans showedline broadening as compared with experiments involving magainin2(Matsuzaki et al., 1998

) and MSI-78 (Hallock et al., 2003

),probably because both L and H_II phases create lipid systemsthat show isotropic motional averaging, as seen in other PC/PElipid mixtures (Cullis et al., 1978

; Tilcock et al., 1982

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FIGURE 2 Differential scanning calorimetry curves of pin2 in DOPE/POPC lipid bilayers. Lipid membranes were composed of DOPE/POPC (6:1) at the given concentrations of pin2. The position of the calorimetry scans is arbitrary.

pH dependence of lipid bilayer alignment in the presence of pin2
To determine the orientation between pin2 and lipid bilayersby NMR solid-state analysis in a fully hydrated system, we requirea strongly magnetic oriented lipid bilayer system, preparedby lipid membrane lysis and re-fusion (Naito et al., 2000

; Kimuraet al., 2002

; Toraya et al., 2003). Hence, elongated and magneticallyorientated lipid bilayers were evaluated under different pHconditions. Fig. 3 shows the ³¹P NMR spectra of lipid bilayersat pH = 7.5 and 3.5 in the presence of pin2, at various temperatures.At pH = 7.5, as the temperature was lowered from 40°C to0°C, the ³¹P signal becomes broadened, due to interferencefrom averaging of the chemical shift anisotropy (CSA) by lateraldiffusion at temperatures below the liquid crystal-gel transitiontemperature (T_m = 24°C) of DMPC and DMPG. When the temperaturewas raised back to 40°C, the same powder pattern was observedas before. At pH = 3.5 and 40°C, increased powder pattern-likecharacter was observed. The small signal at –6 ppm indicatesthe presence of lysolipids in the lipid bilayers, generatedby phospholipid hydrolysis (Naito et al., 2002

) and the signalat 0 ppm is probably caused by lysolipid micellization (Naitoet al., 2002

). The formation of lysolipids was verified by TLCseparation (after NMR measurements) using 1-myristoyl-2-hydroxy-sn-glycero-3-[phospho-rac-(1-glycerol)]and 1-myristoyl-2-hydroxy-sn-glycero-3-phosphocholine as a lysolipidstandard. When the temperature was lowered to 0°C, a narrowsignal was observed. This isotropic narrow signal in the ³¹PNMR spectrum has been reported in several other peptide-containinglipid dispersion systems, such as the melittin-DMPG system (Dufourcqet al., 1986b

), the cyclic peptide gramicidin S-PC/PE system(Prenner et al., 1997

), and the dinorphin A-DMPC system (Naitoet al., 2002

). This isotropic signal may be ascribable to fastisotopic tumbling of phospholipids, caused by a lipid bilayerphase inversion from multilamellar vesicles to another structure,such as micelles, small unilamellar vesicles, small discoidalbilayers (Dufourcq et al., 1986a

), or cubic phases (Prenneret al., 1997

). When the temperature was raised back to 20°C,a mixture of the isotropic components and the powder patterncomponents were observed, indicating the coexistence of an isotropicphase and a lamellar phase. At 40°C, the ${delta}$ _|| component ofthe ³¹P NMR powder pattern disappeared suggesting that the smallmembrane bilayer particles were re-fused to make elongated lipidbilayers during the temperature increase from 0°C to 40°C(Naito et al., 2002

). In summary, membrane lysis of lipid bilayersoccurred under acidic conditions, in the presence of pin2.

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FIGURE 3 ³¹P NMR spectra of phospholipids in lipid bilayers composed of DMPC/DMPG (4:1) in the presence of pin2 (P/L = 1/20) under neutral and acidic pH conditions, at various temperatures. PC and PG indicate the signals of DMPC and DMPG, respectively.

For comparison reasons, we also measured the ³¹P NMR spectraof the same DMPG/DMPC lipid bilayers under neutral and acidicconditions in the presence of mastoparan (INLKALAALAKKIL), awell-known pore-forming peptide from wasp venom, at varioustemperatures (Fig. 4). As with pin2, the isotropic signal wasabsent under neutral conditions, whereas under acidic conditions,the narrow isotropic signal appeared at temperatures below T_m.To date, no isotropic narrow signals indicating membrane lysishave been reported for fully hydrated lipid bilayers in thepresence of mastoparan (Hori et al., 1999

). It was thereforeconcluded that acidic conditions are important for membranefusion and lysis in the presence of pin2 or mastoparan, undermagnetic alignment of the peptide-lipid system. The membranelytic behaviors of mastoparan and pin2 are different, probablydue to the structural differences between the two peptides,such as length or hydrophobicity.

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FIGURE 4 ³¹P NMR spectra of phospholipids in lipid bilayers composed of DMPC/DMPG (4:1) in the presence of mastoparan (P/L = 1/10) under neutral and acidic pH conditions, at various temperatures. PC and PG indicate the signals of DMPC and DMPG, respectively.

Orientation and dynamics of pandinin 2 in lipid bilayers
To determine the relative orientation between pin2 and the lipidbilayers, the ¹³C NMR spectra of five kinds of site-specifically¹³C=O labeled pin2 (Gly³, Gly⁸, Leu¹², Phe¹⁷, and Ser¹⁸) boundto lipid bilayers, were measured. Before each measurement, the³¹P NMR spectra of the samples were acquired to confirm thatthe membrane surface was oriented parallel to the magnetic field.Figs. 5 and 6 show the ¹³C NMR spectra measured under staticand slow MAS conditions, respectively. Table 1 lists the ¹³Cchemical shift values ( ${delta}$ _obs) under static conditions, and theprincipal values of ¹³C=O CP spectra (not shown) of the lyophilizedsamples. The ${delta}$ ₂₂ values show the greatest variation of the principalvalues of Gly³ and Gly^{8 13}C=O chemical shift tensors. This confirmsearlier observations, showing the ${delta}$ ₂₂ value of the Gly¹³C=O CSAtensor is the most dependent on adjacent residues (Separovicet al., 1990

). These principal values show the typical broadasymmetrical powder pattern of carbonyl carbons ( $~$ 150 ppm; Hartzellet al., 1987

). The ¹³C NMR spectra obtained under slow MAS conditions(Fig. 6) also show broad signals, obtained by disturbing themagnetic ordering under slow-speed magic-angle spinning, butthe CSA ( ${delta}$ _||– ${delta}$ ) was $~$ 0–45 ppm, which is smaller thannormal. All of these spectra show an axially symmetrical powderpattern, different to normal. Generally, the principal axisdirections of the carbonyl carbon chemical shift anisotropyin peptides are reported as follows: the ${delta}$ ₁₁ and the ${delta}$ ₂₂ axesare in the peptide plane where the ${delta}$ ₂₂ axis points roughly alongthe C=O bond, between 0° and 12° off the parallel tothe C=O bond direction, and the ${delta}$ ₁₁ axis is perpendicular tothe ${delta}$ ₂₂, whereas the ${delta}$ ₃₃ axis is approximately perpendicular tothe peptide plane (Hartzell et al., 1987

; Separovic et al.,1990

; Wei et al., 2001

). From the slow MAS results, it is presumedthat the ${alpha}$ -helix rapidly rotates around the average helical axisassuming the C=O bond direction is nearly parallel to the helicalaxis (Naito et al., 2000

). Further, the ¹³C=O chemical shiftvalues, ${delta}$ _obs obtained under static conditions (Fig. 5), are closeto the ${delta}$ values (Fig. 6), indicating that the rotating axis isparallel to the lipid long axis (Toraya et al., 2004

). Duringthe slow MAS study the values and signs of the CSA ( ${delta}$ _||– ${delta}$ )vary from residue to residue, suggesting that the C=O ( ${delta}$ ₂₂) directiondeviates angle ß (–90° $≤$ ß <90°) from the membrane normal, perpendicular to the magneticfield. Therefore, the peptide plane makes an angle ${alpha}$ (0° $≤$ ${alpha}$ < 360°) with the Z–D plane as shown in Fig. 7(Toraya et al., 2004

). Fig. 8 shows the simulated ¹³C NMR spectrausing ${delta}$ ₁₁, ${delta}$ ₂₂, and ${delta}$ ₃₃ values of 247, 184, and 88 ppm, respectively,on the basis of the CP spectra of lyophilized Gly³ C=O labeledpin2 at ß = 0°, 20°, and 40°. The lineshapesof the spectrum are similar for any of the following orientations:( ${alpha}$ , ß), (– ${alpha}$ , ß), ( ${pi}$ – ${alpha}$ , ß),(– ${pi}$ + ${alpha}$ , ß), ( ${alpha}$ , –ß), (– ${alpha}$ ,–ß), ( ${pi}$ – ${alpha}$ , –ß), (– ${pi}$ + ${alpha}$ , –ß). The values and signs of the CSA varydepending on the ${alpha}$ - and ß-angles. Hence, by comparingthe experimental and simulated lineshapes for the five kindsof ¹³C=O labeled pin2, and assigning the difference of ${alpha}$ -anglebetween the neighboring peptide plane as 100° ±10°,the ß-orientations could be determined. The carbonylregion of the ¹³C NMR spectra of a variety of ¹³C-labeled pin2,bound to lipid bilayers, obtained under slow MAS conditionswith their best-fit simulated spectra superposed, are shownin Fig. 9 a. The best ß-orientations are listed inTable 1. From this result, we can determine that the N- andC-terminal helical rods are inclined $~$ 45°, with the middlesection inclined $~$ 25° to the average helical axis (lipidlong axis). Based on these data, a structural model of pin2in a lipid bilayer can be proposed as in Fig. 9 b.

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FIGURE 5 Carbonyl region of the ¹³C NMR spectra of a variety of ¹³C-labeled pin2, bound to lipid bilayers (P/L = 1/20) under static conditions, at 40°. Asterisks denote the phospholipid C=O group. Triangles denote unknown impurities.

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FIGURE 6 Carbonyl region of the ¹³C NMR spectra of a variety of ¹³C-labeled pin2 bound to lipid bilayers (P/L = 1/20) under slow MAS conditions ( ${omega}$ _R = 100 Hz) at 40°C. Asterisks denote the phospholipid C=O group.

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TABLE 1 ¹³C=O chemical shift values and ß-angles of ¹³C-labeled peptides

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FIGURE 7 Schematic representation of the coordinate frames in which the orientation and dynamics of pin2 were defined. The bilayer normal D is perpendicular to the magnetic field B_o. D is identical to the average helix axis. The value ß is the tilt angle of helix axis (Z) from D. Z is identical to the ${delta}$ ₂₂ principal axis of C=O chemical shift tensor. The value ${alpha}$ is the angle between a peptide plane and a Z–D plane.

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FIGURE 8 The ${alpha}$ -angle dependence of the carbonyl region in simulated ¹³C NMR spectra. The principal values of carbonyl carbon of Gly³, ${delta}$ ₁₁ = 247, ${delta}$ ₂₂ = 184, and ${delta}$ ₃₃ = 88 ppm. The ß-angle is fixed at 0°, 20°, and 40°.

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FIGURE 9 (a) ¹³C NMR spectra showing the carbonyl regions for a variety of ¹³C-labeled pin2 bound to lipid bilayers (P/L = 1/20) under slow MAS conditions (solid line, same as Fig. 5), with the best-fit simulated spectra (dotted line) superimposed. (b) Proposed model for orientation of pin2 in lipid bilayers.

Amide H-D exchange
To understand how pin2 interacts with the lipid membrane, theamide H-D exchange of ¹⁵N-labeled pin2 was examined (Williamset al., 1996

; Almeida and Opella, 1997

). Fig. 10 shows the HSQCspectra measured at 5, 30, and 60 min after adding D₂O to amixture of 3 mM ¹⁵N-Ala⁴, Gly⁸, and Ala⁹ triply-labeled pin2and 120 mM DPC micelles. The amide proton of residue Ala⁴ underwent>50% exchange after 5 min and the exchange was complete within30 min; hence it was classified as a fast exchange. The amideproton of residue Ala⁹ showed little exchange after 5 min, andincomplete exchange after 60 min; hence it was classified asa slow exchange. Lastly, the amide proton of residue Gly⁸ underwentmoderate exchange. The varying amounts of amide exchange wouldindicate that Ala⁴ is exposed to the aqueous environment whereasAla⁹ is located in a hydrophobic micelle region, and Gly⁸ bordersthese regions. These results are in good agreement with thehydrophobicity of pin2 as shown in Fig. 11 a. According to the¹³C NMR pin2 orientation and dynamics studies, the average helicalaxis of pin2 penetrates perpendicular to the bilayer membrane.Together, the amide H-D exchange and ¹³C NMR data would indicatethat pin2 forms pores by monomer association, where Ala⁴ facesthe aqueous environment of the pore and Ala⁹ faces the acylchains of the membrane. Although we presume that the ${alpha}$ -helixof pin2 laterally diffuses while rapidly rotating around themembrane normal, the amide H-D exchange results suggest thatthe helix bundle might rapidly rotate around the membrane normal.This rotation is essentially the same as the rotation of the ${alpha}$ -helix around the membrane normal. If the helix bundle of pin2laterally diffuses into the lipids of the lipid bilayer, thenrotation around the membrane normal is essentially the sameas the lateral diffusion of the helix bundle.

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FIGURE 10 ¹⁵N-¹H HSQC spectra of ¹⁵N-Ala⁴, Gly⁸, Ala⁹ triply labeled pin2 (3 mM) in DPC micelles (P/L = 1/40) at 40°C after amide H-D exchange at (a) 5 min, (b) 30 min, and (c) 60 min.

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FIGURE 11 (a) Helical-wheel projection of pin2 (the ¹⁵N-labeled residues are indicated by asterisks), (b) Helical net representations, and (c) model for mechanism of pin2 pore formation. Hydrophobicity of each amino acid is represented in shading with the most polar residues in rendered in solid symbols for a and b.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

Pore-forming mechanisms that have been proposed to explain themode of action of ${alpha}$ -helical membrane peptides include the transmembrane-helicalbundle, the carpet-like, and the toroidal models. However, ${alpha}$ -helicalmembrane peptides can adopt more than one pore-forming mechanism,depending on experimental conditions. For example, the pore-formingmechanism of pardaxin depends on the type of membranes used.Solid-state NMR studies of pardaxin showed it to adopt a carpet-typeorientation in lipid bilayers composed of 1-palmitoyl-2-oleoyl-phosphatidylcholine(POPC), but displayed a transmembrane orientation in lipid bilayerscomposed of DMPC (Hallock et al., 2002

). LAH₄, a pore-formingpeptide, exhibited carpet-type orientation under acidic conditions,but a transmembrane orientation at neutral pH (Bechinger, 1996

).Even under similar experimental conditions, mastoparan simultaneouslyexhibited two distinct orientations; 10% transmembrane and 90%carpet-type (Hori et al., 2001

). Therefore, the study of peptidepore-forming mechanisms is highly dependent on experimentalconditions, since the peptides can adopt different orientationsin response to their environment.

The DSC measurements (Fig. 2) suggested that pin2 induces negativecurvature strain in lipid bilayers, unlike other peptides suchas magainin2 (Matsuzaki et al., 1998) and MSI-78 (Hallock etal., 2003), which induce a positive curvature. It has been proposedthat peptide hydrophobicity dictates this behavior, and is dependenton the position of the hydrophobic amino acids in the peptidesequence (Tachi et al., 2002). When hydrophobic residues areclustered, the deepest penetrating portion of the peptide willsignificantly expand the hydrophobic core of the bilayer andinduce negative curvature. Fig. 11 b compares helical net representations(Tachi et al., 2002), where hydrophobicity is referred to ashydropathy index (Kyte and Doolittle, 1982). Fig. 11, a andb, show the hydrophobic residues of pin2 are more ordered andmore hydrophobic than those in magainin2 or MSI-78. Therefore,it is likely that this clustering of hydrophobic residues enablespin2 to penetrate further into the lipid bilayer and inducenegative curvature strain on the bilayer.

Concerning the biological activity of pin2 on lipid membranes,we should clarify the difference between antimicrobial and hemolyticactivities, and membrane lysis (Figs. 3 and 4). Membrane lysiswas observed under acidic conditions and temperatures belowT_m where the membranes were completely broken, with no tracesof the original bilayer remaining. However, lysed or completelybroken membranes are not a requisite for antimicrobial or hemolyticactivities, which can occur when molecules leak through a membranepore.

The ¹³C solid-state NMR data and subsequent analyses (Figs. 5–9 ) showed the orientation of pin2 within a lipid bilayerand the dynamics in the membrane mimetic environment. As a comparison,melittin in a mechanically oriented DTPC bilayer system withglass plates also shows a transmembrane orientation (Smith etal., 1994); i.e., melittin reorients around the bilayer normalillustrated by the 90°-oriented spectra showing large chemicalshift anisotropy below T_m, observable from the carbonyl chemicalshift values varying from different residues. In highly hydratedsystems, melittin forms a transmembrane ${alpha}$ -helix in the lipidbilayer and laterally diffuses via rapidly rotating around themembrane normal (Naito et al., 2000), where the local helicalaxis rotates around the membrane normal, making an angle of±30° and ±10° in a DMPC bilayer system(Naito et al., 2000), or –36° and 25° in a DPPCbilayer system (Toraya et al., 2004) for the N- and C-terminalhelical rods, respectively. Pin2 in the present DMPC/DMPG bilayersystem also laterally diffuses by rapidly rotating around themembrane normal. Since a high-resolution structure of pin2,determined by solution NMR, showed no significant kink aroundproline, we suggest that the angles between the local helicalaxis and the average helical axis of pin2 have similar signsfor the N- and C-terminals and around Leu¹². Therefore, thelocal helical axis may proceed around the bilayer normal bymaking an angle of 45° for the N- and C-terminal helicalrods and 25° around Leu¹², and pin2 may be doubly kinkedaround Leu¹² in DMPC/DMPG lipid bilayers as shown in Fig. 9 b.Other peptides have also shown steep tilt angles and similarrotational motions. For example, Protegrin-1, a ß-sheetantimicrobial peptide, is tilted by 55° from the DLPC bilayernormal (Yamaguchi et al., 2002), and rotates uniaxially aroundthe bilayer normal. The helix-break-helix fusogenic peptideB18 shows a tilt angle of 54° in DMPC/DMPG (4:1) lipid bilayersand binds to membranes in a boomerang-like fashion (Afonin etal., 2004). The steep tilt angles and rotation around the bilayernormal might be a requisite for certain types of pore-formingpeptides.

We propose a pore-forming mechanism for the action of pin2 onDMPG/DMPC lipid bilayers, based on our orientation and dynamicNMR studies. The DSC measurements show that pin2 induces negativecurvature strain in lipid bilayers, implying that deep penetrationof pin2 significantly expands the hydrophobic core of the lipidbilayer, providing a driving force for further penetration intothe membrane (Fig. 11 c). The pin2 average helical axis is orientedperpendicular to the membrane surface, with the N(Gly³)- andC(Ser¹⁸)-terminal helical rods inclined at $~$ 45° to the averagehelical axis (Table 1). Pin2 probably forms an open ${alpha}$ -helicalbundle or twisted-barrel type oligomer by self-association,where a pore is formed within the peptide complex. At temperaturesbelow T_m the lateral diffusion rate slows down, suggesting thatthe pores associate with each other. The small area of lipidbilayer surrounded by peptides would then form a small discoidalbilayer which would disperse, as previously observed by Dufourcqet al. (1986a) and Naito et al. (2000). The static ³¹P NMR isotropicsignal reveals the isotropic dispersion of the small discoidalbilayers. Moreover, the static ¹³C=O NMR spectrum of Gly³ alsoshows an isotropic signal below T_m (not shown), even thoughthe lateral diffusion rate of both lipids and peptides becomesslow at temperatures below T_m.

In conclusion, this article demonstrates a novel pore-formingmechanism for ${alpha}$ -helical peptides.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

We thank Prof. Matsuzaki for helpful discussion. We are gratefulto Prof. Aimoto for the usage of the Microcal MCS calorimeter.We also thank Dr. M. Horikawa for synthesizing the ¹³C=O labeledFmoc amino acid, Dr. E. Villegas for help during peptide synthesis,and Drs. M. Hisada and K. Masuda for acquiring the mass spectraof synthetic peptides.

FOOTNOTES

Abbreviations used: DLPC, 1,2-dilauroyl-sn-glycero-3-phosphatidylcholine;DMPC, 1,2-dimyristoyl-sn-glycero-3-phosphatidylcholine; DMPG,2-dimyristoyl-sn-glycero-3-phosphatidylglycerol; DOPE, 1,2-dioleoyl-sn-glycero-3-phosphatidylethanolamine;DPC, dodecylphosphocholine; DSC, differential scanning calorimetry;DTPC, 1,2-ditetradecyl-sn-glycero-3-phosphatidylcholine; HPLC,high-performance liquid chromatography; HSQC, heteronuclearsingle quantum coherence; MALDI-TOF, matrix-assisted laser-desorptionionization-time-flight; MAS, magic-angle spinning; ODS, octadecyl silica; PC, phosphatidylcholine; PE, phosphatidylethanolamine;pin2, pandinin 2; POPC, 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidylcholine;TPPI, time-proportional phase-incrementation.

Submitted on March 28, 2004; accepted for publication July 29, 2004.

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