Presentation is loading. Please wait.

Presentation is loading. Please wait.

Membrane Perturbation Induced by Interfacially Adsorbed Peptides

Published byErick Baker Modified over 4 years ago

Similar presentations

Presentation on theme: "Membrane Perturbation Induced by Interfacially Adsorbed Peptides"— Presentation transcript:

1 Membrane Perturbation Induced by Interfacially Adsorbed Peptides
Assaf Zemel, Avinoam Ben-Shaul, Sylvio May  Biophysical Journal  Volume 86, Issue 6, Pages (June 2004) DOI: /biophysj Copyright © 2004 The Biophysical Society Terms and Conditions

2 Figure 1 Schematic illustration of a lipid bilayer with adsorbed, partially inserted α-helical peptides on its upper (“external”) monolayer. The high peptide concentration results in nematic orientational order of the peptides’ long axes. The dashed lines denote the boundaries of a unit cell; some lipids are depicted schematically. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

3 Figure 2 Schematic illustration of a lipid bilayer section (the “unit cell”) containing one, partially inserted, amphipathic peptide. The depth of insertion p defines the insertion angle α corresponding to the peptide sector facing the aqueous environment. In general, this angle is equal to the peptide's polar angle. The (average) interaxial distance between neighboring peptides is L. Note that the thickness of the membrane's hydrocarbon core, h, is assumed to be constant throughout the membrane. Some lipids are depicted schematically. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

4 Figure 3 The perturbation of a lipid bilayer induced by an amphipathic peptide rod (hatched circle) of radius rP=6Å and insertion (polar) angle α=π. Shown is a cross section of (one half of) a unit cell in the x, z plane; the peptide axis is oriented along the y direction. The membrane thickness is h=26Å, and the lipid/peptide ratio is N=80, implying L=44Å. For some arbitrarily chosen headgroup locations (small circles at z=0 and z=26Å) along the x axis, the strings of connected circles represent the calculated average positions of the (15, including the one marking the headgroup position) segments, of six representative lipid chains; three from each leaflet. The shaded regions surrounding the chains represent the shape of the volumes accounting for 85% of their possible conformations—qualitatively describing the chain extensions; see text for further explanations. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

5 Figure 4 Density of headgroups, σE(x) and σI(x), in the external and internal monolayers, respectively, calculated for the lipid bilayer corresponding to that in Fig. 3. Note, to obtain the full spatial extension of headgroup density modulations, the results shown here are for a single peptide in a large membrane, i.e., for the limit N→∞; the results obtained for N=80 are essentially the same. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

6 Figure 5 Calculated C-H bond order parameter, −Sn, for various hydrophobic thicknesses h and peptide penetration depths p. The different curves refer to h=26Å, p=6Å (○); h=26Å, p=14Å ((); h=24Å, p=6Å ((); and h=26Å, p=20Å (★). The values Sn=Sn0, for an unperturbed (peptide-free) bilayer of hydrophobic thickness h=h*=26Å, are indicated by the dashed line. The inset shows the corresponding differences in order parameter, ΔSn=Sn−Sn0, relative to the unperturbed, peptide-free bilayer. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

7 Figure 6 C-H bond order parameters, −Sn, calculated for lipid chains residing at positions x=1Å ((), x=7Å ((), x=13Å ((), and x=19Å (★). As a comparison, the dashed lines show-Sn for an unperturbed lipid layer. The calculation was performed for p=6Å and h=h*=26Å; the left and right panels refer to the external and internal monolayer, respectively. Note that the selected x positions in each monolayer match those for which the chains are displayed in Fig. 3. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

8 Figure 7 Average cross-sectional area per lipid tail aL (upper panel) and average conformational free energy per lipid tail, (Fc(p, h)/N, measured with respect to an unperturbed (peptide-free) membrane of thickness h=h*=26Å (lower panel). In both panels. the different curves refer to h=22Å (*), h=24Å (★), h=26Å ((), h=28Å ((), and h=30Å ((). All calculations are based on a lipid/peptide ratio of N=80. The curves are plotted as a function of the peptide's penetration depth, p (see Fig. 2), starting at p=0 and ending at p=h+2rP for which the peptide is translocated through the whole hydrocarbon core of the bilayer. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

9 Figure 8 The excess free energy per lipid chain, (F(p, h)/N (see Eq. 23) with γ=0.08kBT/Å2, as a function of membrane thickness h for a peptide-free membrane ((), for p=6Å ((), for p=12Å ((), and for p=18Å (★). At any given peptide penetration depth, p, there is one particular membrane thickness, h=heq, for which (F(p, h)/N adopts a minimum. The corresponding dependence, heq(p), is displayed in the inset. The solid line in the inset interpolates between the symbols, calculated at p=0, 6, 12, and 18Å. Note, our choice γ=0.08kBT/Å2 ensures the thickness of a bare, peptide-free membrane to be heq(p=0)=26Å. The lipid/peptide ratio is N=80. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

10 Figure 9 Transfer free energy, (Ftot, per peptide for γP=0 ((), for γP=0.02 kBT/Å2 ((), and for γP=0.08 kBT/Å2 ((), plotted as a function of the angular size, α, of the polar helix face (see Fig. 2). For α=90°, 180°, and 270°, we schematically picture the size of the polar face (shaded regions), indicating the corresponding peptide penetration into the membrane. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

11 Figure 10 Excess free energy, (F, per peptide rod, as a function of 1/L for h=18Å ((), h=20Å ((), h=22Å ((), h=24Å (*), and h=26Å (★). The broken line denotes the minimal value of (F, calculated for optimal thickness, h=heq(1/L). The corresponding values for the optimal thickness, heq, are shown in the inset as a function of peptide/lipid ratio, 1/N (solid line). The relation between N and L is given by Eq. 27. The broken line in the inset shows the prediction for h=heq(1/N) according to Eq. 28 with aL=31.2Å2 and aP=360Å2. All results are derived for a peptide penetration depth of p=rP=6Å. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2004 The Biophysical Society Terms and Conditions

Download ppt "Membrane Perturbation Induced by Interfacially Adsorbed Peptides"

Similar presentations

Biophysical Regulation of Lipid Biosynthesis in the Plasma Membrane

Biophysical Regulation of Lipid Biosynthesis in the Plasma Membrane
Volume 100, Issue 10, Pages (May 2011)

Volume 100, Issue 10, Pages (May 2011)
Peter J. Mulligan, Yi-Ju Chen, Rob Phillips, Andrew J. Spakowitz 

Peter J. Mulligan, Yi-Ju Chen, Rob Phillips, Andrew J. Spakowitz 
Vishwanath Jogini, Benoît Roux  Biophysical Journal 

Vishwanath Jogini, Benoît Roux  Biophysical Journal 
Molecular Dynamics Simulations of the Lipid Bilayer Edge

Molecular Dynamics Simulations of the Lipid Bilayer Edge
Mechanism of the Lamellar/Inverse Hexagonal Phase Transition Examined by High Resolution X-Ray Diffraction  Michael Rappolt, Andrea Hickel, Frank Bringezu,

Mechanism of the Lamellar/Inverse Hexagonal Phase Transition Examined by High Resolution X-Ray Diffraction  Michael Rappolt, Andrea Hickel, Frank Bringezu,
Influence of Chain Length and Unsaturation on Sphingomyelin Bilayers

Influence of Chain Length and Unsaturation on Sphingomyelin Bilayers
R. Jay Mashl, H. Larry Scott, Shankar Subramaniam, Eric Jakobsson 

R. Jay Mashl, H. Larry Scott, Shankar Subramaniam, Eric Jakobsson 
Langevin Dynamics Simulations of Genome Packing in Bacteriophage

Langevin Dynamics Simulations of Genome Packing in Bacteriophage
Morphology of the Lamellipodium and Organization of Actin Filaments at the Leading Edge of Crawling Cells  Erdinç Atilgan, Denis Wirtz, Sean X. Sun  Biophysical.

Morphology of the Lamellipodium and Organization of Actin Filaments at the Leading Edge of Crawling Cells  Erdinç Atilgan, Denis Wirtz, Sean X. Sun  Biophysical.
Jeremy D. Wilson, Chad E. Bigelow, David J. Calkins, Thomas H. Foster 

Jeremy D. Wilson, Chad E. Bigelow, David J. Calkins, Thomas H. Foster 
Volume 90, Issue 4, Pages (February 2006)

Volume 90, Issue 4, Pages (February 2006)
Volume 104, Issue 1, Pages (January 2013)

Volume 104, Issue 1, Pages (January 2013)
J. Leng, S.U. Egelhaaf, M.E. Cates  Biophysical Journal 

J. Leng, S.U. Egelhaaf, M.E. Cates  Biophysical Journal 
Volume 104, Issue 3, Pages (February 2013)

Volume 104, Issue 3, Pages (February 2013)
Volume 85, Issue 2, Pages (August 2003)

Volume 85, Issue 2, Pages (August 2003)
Felix Campelo, Harvey T. McMahon, Michael M. Kozlov 

Felix Campelo, Harvey T. McMahon, Michael M. Kozlov 
Membrane Thickening by the Antimicrobial Peptide PGLa

Membrane Thickening by the Antimicrobial Peptide PGLa
Volume 87, Issue 4, Pages (October 2004)

Volume 87, Issue 4, Pages (October 2004)
Experimental and Computational Studies Investigating Trehalose Protection of HepG2 Cells from Palmitate-Induced Toxicity  Sukit Leekumjorn, Yifei Wu,

Experimental and Computational Studies Investigating Trehalose Protection of HepG2 Cells from Palmitate-Induced Toxicity  Sukit Leekumjorn, Yifei Wu,

Similar presentations

Ads by Google