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\begin{document} |
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%\bibliographystyle{aps} |
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\title{Dipolar Ordering of the Ripple Phase in Lipid Membranes} |
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\author{Xiuquan Sun and J. Daniel Gezelter} |
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\email[E-mail:]{gezelter@nd.edu} |
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\affiliation{Department of Chemistry and Biochemistry,\\ |
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University of Notre Dame, \\ |
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\title{Dipolar Ordering in Molecular-scale Models of the Ripple Phase |
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in Lipid Membranes} |
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\author{Xiuquan Sun and J. Daniel Gezelter \\ |
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Department of Chemistry and Biochemistry,\\ |
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University of Notre Dame, \\ |
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Notre Dame, Indiana 46556} |
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%\email[E-mail:]{gezelter@nd.edu} |
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\date{\today} |
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\begin{abstract} |
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\maketitle |
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|
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\begin{abstract} |
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The ripple phase in phosphatidylcholine (PC) bilayers has never been |
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completely explained. |
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\end{abstract} |
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\pacs{} |
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\maketitle |
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%\maketitle |
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\section{Introduction} |
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\label{sec:Int} |
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Fully hydrated lipids will aggregate spontaneously to form bilayers |
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which exhibit a variety of phases depending on their temperatures and |
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compositions. Among these phases, a periodic rippled phase |
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($P_{\beta'}$) appears as an intermediate phase between the gel |
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($L_\beta$) and fluid ($L_{\alpha}$) phases for relatively pure |
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phosphatidylcholine (PC) bilayers. The ripple phase has attracted |
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substantial experimental interest over the past 30 years. Most |
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structural information of the ripple phase has been obtained by the |
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X-ray diffraction~\cite{Sun96,Katsaras00} and freeze-fracture electron |
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microscopy (FFEM).~\cite{Copeland80,Meyer96} Recently, Kaasgaard {\it |
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et al.} used atomic force microscopy (AFM) to observe ripple phase |
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morphology in bilayers supported on mica.~\cite{Kaasgaard03} The |
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experimental results provide strong support for a 2-dimensional |
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hexagonal packing lattice of the lipid molecules within the ripple |
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phase. This is a notable change from the observed lipid packing |
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within the gel phase.~\cite{Cevc87} |
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|
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As one of the most important components in the formation of the |
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biomembrane, lipid molecules attracted numerous studies in the past |
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several decades. Due to their amphiphilic structure, when dispersed in |
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water, lipids can self-assemble to construct a bilayer structure. The |
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phase behavior of lipid membrane is well understood. The gel-fluid |
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phase transition is known as main phase transition. However, there is |
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an intermediate phase between gel and fluid phase for some lipid (like |
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phosphatidycholine (PC)) membranes. This intermediate phase |
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distinguish itself from other phases by its corrugated membrane |
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surface, therefore this phase is termed ``ripple'' ($P_{\beta '}$) |
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phase. The phase transition between gel-fluid and ripple phase is |
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called pretransition. Since the pretransition usually occurs in room |
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temperature, there might be some important biofuntions carried by the |
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ripple phase for the living organism. |
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A number of theoretical models have been presented to explain the |
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formation of the ripple phase. Marder {\it et al.} used a |
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curvature-dependent Landau-de Gennes free-energy functional to predict |
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a rippled phase.~\cite{Marder84} This model and other related continuum |
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models predict higher fluidity in convex regions and that concave |
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portions of the membrane correspond to more solid-like regions. |
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Carlson and Sethna used a packing-competition model (in which head |
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groups and chains have competing packing energetics) to predict the |
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formation of a ripple-like phase. Their model predicted that the |
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high-curvature portions have lower-chain packing and correspond to |
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more fluid-like regions. Goldstein and Leibler used a mean-field |
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approach with a planar model for {\em inter-lamellar} interactions to |
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predict rippling in multilamellar phases.~\cite{Goldstein88} McCullough |
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and Scott proposed that the {\em anisotropy of the nearest-neighbor |
80 |
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interactions} coupled to hydrophobic constraining forces which |
81 |
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restrict height differences between nearest neighbors is the origin of |
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the ripple phase.~\cite{McCullough90} Lubensky and MacKintosh |
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introduced a Landau theory for tilt order and curvature of a single |
84 |
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membrane and concluded that {\em coupling of molecular tilt to membrane |
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curvature} is responsible for the production of |
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ripples.~\cite{Lubensky93} Misbah, Duplat and Houchmandzadeh proposed |
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that {\em inter-layer dipolar interactions} can lead to ripple |
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instabilities.~\cite{Misbah98} Heimburg presented a {\em coexistence |
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model} for ripple formation in which he postulates that fluid-phase |
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line defects cause sharp curvature between relatively flat gel-phase |
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regions.~\cite{Heimburg00} Kubica has suggested that a lattice model of |
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polar head groups could be valuable in trying to understand bilayer |
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phase formation.~\cite{Kubica02} Bannerjee used Monte Carlo simulations |
94 |
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of lamellar stacks of hexagonal lattices to show that large headgroups |
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and molecular tilt with respect to the membrane normal vector can |
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cause bulk rippling.~\cite{Bannerjee02} |
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|
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The ripple phase is observed experimentally by x-ray diffraction |
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~\cite{Sun96,Katsaras00}, freeze-fracture electron microscopy |
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(FFEM)~\cite{Copeland80,Meyer96}, and atomic force microscopy (AFM) |
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recently~\cite{Kaasgaard03}. The experimental studies suggest two |
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kinds of ripple structures: asymmetric (sawtooth like) and symmetric |
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(sinusoidal like) ripple phases. Substantial number of theoretical |
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explaination applied on the formation of the ripple |
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phases~\cite{Marder84,Carlson87,Goldstein88,McCullough90,Lubensky93,Misbah98,Heimburg00,Kubica02,Bannerjee02}. |
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In contrast, few molecular modelling have been done due to the large |
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size of the resulting structures and the time required for the phases |
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of interest to develop. One of the interesting molecular simulations |
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was carried out by De Vries and Marrink {\it et |
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al.}~\cite{deVries05}. According to their dynamic simulation results, |
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the ripple consists of two domains, one is gel bilayer, and in the |
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other domain, the upper and lower leaves of the bilayer are fully |
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interdigitated. The mechanism of the formation of the ripple phase in |
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their work suggests the theory that the packing competition between |
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head group and tail of lipid molecules is the driving force for the |
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formation of the ripple phase~\cite{Carlson87}. Recently, the ripple |
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phase is also studied by using monte carlo simulation~\cite{Lenz07}, |
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the ripple structure is similar to the results of Marrink except that |
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the connection of the upper and lower leaves of the bilayer is an |
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interdigitated line instead of the fully interdigitated |
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domain. Furthermore, the symmetric ripple phase was also observed in |
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their work. They claimed the mismatch between the size of the head |
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group and tail of the lipid molecules is the driving force for the |
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formation of the ripple phase. |
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In contrast, few large-scale molecular modelling studies have been |
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done due to the large size of the resulting structures and the time |
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required for the phases of interest to develop. With all-atom (and |
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even unified-atom) simulations, only one period of the ripple can be |
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observed and only for timescales in the range of 10-100 ns. One of |
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the most interesting molecular simulations was carried out by De Vries |
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{\it et al.}~\cite{deVries05}. According to their simulation results, |
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the ripple consists of two domains, one resembling the gel bilayer, |
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while in the other, the two leaves of the bilayer are fully |
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interdigitated. The mechanism for the formation of the ripple phase |
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suggested by their work is a packing competition between the head |
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groups and the tails of the lipid molecules.\cite{Carlson87} Recently, |
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the ripple phase has also been studied by Lenz and Schmid using Monte |
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Carlo simulations.\cite{Lenz07} Their structures are similar to the De |
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Vries {\it et al.} structures except that the connection between the |
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two leaves of the bilayer is a narrow interdigitated line instead of |
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the fully interdigitated domain. The symmetric ripple phase was also |
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observed by Lenz {\it et al.}, and their work supports other claims |
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that the mismatch between the size of the head group and tail of the |
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lipid molecules is the driving force for the formation of the ripple |
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phase. Ayton and Voth have found significant undulations in |
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zero-surface-tension states of membranes simulated via dissipative |
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particle dynamics, but their results are consistent with purely |
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thermal undulations.~\cite{Ayton02} |
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|
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Although the organizations of the tails of lipid molecules are |
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addressed by these molecular simulations, the ordering of the head |
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group in ripple phase is still not settlement. We developed a simple |
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``web of dipoles'' spin lattice model which provides some physical |
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insight in our previous studies~\cite{Sun2007}, we found the dipoles |
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on head groups of the lipid molecules are ordered in an |
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antiferroelectric state. The similiar phenomenon is also observed by |
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Tsonchev {\it et al.} when they studied the formation of the |
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nanotube\cite{Tsonchev04}. |
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Although the organization of the tails of lipid molecules are |
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addressed by these molecular simulations and the packing competition |
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between headgroups and tails is strongly implicated as the primary |
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driving force for ripple formation, questions about the ordering of |
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the head groups in ripple phase has not been settled. |
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|
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In this paper, we made a more realistic coarse-grained lipid model to |
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understand the primary driving force for membrane corrugation and to |
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elucidate the organization of the anisotropic interacting head group |
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via molecular dynamics simulation. We will talk about our model and |
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methodology in section \ref{sec:method}, and details of the simulation |
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in section \ref{sec:experiment}. The results are shown in section |
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\ref{sec:results}. At last, we will discuss the results in section |
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In a recent paper, we presented a simple ``web of dipoles'' spin |
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lattice model which provides some physical insight into relationship |
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between dipolar ordering and membrane buckling.\cite{Sun2007} We found |
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that dipolar elastic membranes can spontaneously buckle, forming |
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ripple-like topologies. The driving force for the buckling in dipolar |
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elastic membranes the antiferroelectric ordering of the dipoles, and |
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this was evident in the ordering of the dipole director axis |
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perpendicular to the wave vector of the surface ripples. A similiar |
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phenomenon has also been observed by Tsonchev {\it et al.} in their |
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work on the spontaneous formation of dipolar peptide chains into |
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curved nano-structures.\cite{Tsonchev04,Tsonchev04II} |
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|
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In this paper, we construct a somewhat more realistic molecular-scale |
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lipid model than our previous ``web of dipoles'' and use molecular |
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dynamics simulations to elucidate the role of the head group dipoles |
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in the formation and morphology of the ripple phase. We describe our |
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model and computational methodology in section \ref{sec:method}. |
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Details on the simulations are presented in section |
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\ref{sec:experiment}, with results following in section |
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\ref{sec:results}. A final discussion of the role of dipolar heads in |
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the ripple formation can be found in section |
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\ref{sec:discussion}. |
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|
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\section{Methodology and Model} |
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\section{Computational Model} |
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\label{sec:method} |
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|
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Our idea for developing a simple and reasonable lipid model to study |
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the ripple phase of lipid bilayers is based on two facts: one is that |
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the most essential feature of lipid molecules is their amphiphilic |
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structure with polar head groups and non-polar tails. Another fact is |
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that dominant numbers of lipid molecules are very rigid in ripple |
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phase which allows the details of the lipid molecules neglectable. The |
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lipid model is shown in Figure \ref{fig:lipidMM}. Figure |
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\ref{fig:lipidMM}a shows the molecular strucure of a DPPC molecule. The |
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hydrophilic character of the head group is the effect of the strong |
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dipole composed by a positive charge sitting on the nitrogen and a |
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negative charge on the phosphate. The hydrophobic tail consists of |
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fatty acid chains. In our model shown in Figure \ref{fig:lipidMM}b, |
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lipid molecules are represented by rigid bodies made of one head |
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sphere with a point dipole sitting on it and one ellipsoid tail, the |
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direction of the dipole is fixed to be perpendicular to the tail. The |
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breadth and length of tail are $\sigma_0$, $3\sigma_0$. The diameter |
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of heads varies from $1.20\sigma_0$ to $1.41\sigma_0$. The model of |
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the solvent in our simulations is inspired by the idea of ``DPD'' |
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water. Every four water molecules are reprsented by one sphere. |
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|
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\begin{figure}[htb] |
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\centering |
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\includegraphics[width=\linewidth]{lipidMM} |
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\caption{The molecular structure of a DPPC molecule and the |
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coars-grained model for PC molecules.\label{fig:lipidMM}} |
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\includegraphics[width=4in]{lipidModels} |
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\caption{Three different representations of DPPC lipid molecules, |
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including the chemical structure, an atomistic model, and the |
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head-body ellipsoidal coarse-grained model used in this |
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work.\label{fig:lipidModels}} |
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\end{figure} |
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|
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Spheres interact each other with Lennard-Jones potential |
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\begin{eqnarray*} |
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V_{ij} = 4\epsilon \left[\left(\frac{\sigma_0}{r_{ij}}\right)^{12} - |
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\left(\frac{\sigma_0}{r_{ij}}\right)^6\right] |
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\end{eqnarray*} |
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here, $\sigma_0$ is diameter of the spherical particle. $r_{ij}$ is |
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the distance between two spheres. $\epsilon$ is the well depth. |
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Dipoles interact each other with typical dipole potential |
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\begin{eqnarray*} |
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V_{ij} = \frac{|\mu|^2}{4 \pi \epsilon_0 r_{ij}^3} |
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\left[ \hat{\bf u}_i \cdot \hat{\bf u}_j - 3 (\hat{\bf u}_i \cdot |
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\hat{\bf r}_{ij})(\hat{\bf u}_j \cdot \hat{\bf r}_{ij}) \right] |
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\end{eqnarray*} |
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In this potential, $\mathbf{\hat u}_i$ is the unit vector pointing |
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along dipole $i$ and $\mathbf{\hat r}_{ij}$ is the unit vector |
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pointing along the inter-dipole vector $\mathbf{r}_{ij}$. Identical |
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ellipsoids interact each other with Gay-Berne potential. |
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\begin{eqnarray*} |
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Our simple molecular-scale lipid model for studying the ripple phase |
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is based on two facts: one is that the most essential feature of lipid |
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molecules is their amphiphilic structure with polar head groups and |
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non-polar tails. Another fact is that the majority of lipid molecules |
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in the ripple phase are relatively rigid (i.e. gel-like) which makes |
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some fraction of the details of the chain dynamics negligible. Figure |
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\ref{fig:lipidModels} shows the molecular strucure of a DPPC |
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molecule, as well as atomistic and molecular-scale representations of |
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a DPPC molecule. The hydrophilic character of the head group is |
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largely due to the separation of charge between the nitrogen and |
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phosphate groups. The zwitterionic nature of the PC headgroups leads |
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to abnormally large dipole moments (as high as 20.6 D), and this |
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strongly polar head group interacts strongly with the solvating water |
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layers immediately surrounding the membrane. The hydrophobic tail |
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consists of fatty acid chains. In our molecular scale model, lipid |
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molecules have been reduced to these essential features; the fatty |
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acid chains are represented by an ellipsoid with a dipolar ball |
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perched on one end to represent the effects of the charge-separated |
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head group. In real PC lipids, the direction of the dipole is |
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nearly perpendicular to the tail, so we have fixed the direction of |
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the point dipole rigidly in this orientation. |
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|
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The ellipsoidal portions of the model interact via the Gay-Berne |
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potential which has seen widespread use in the liquid crystal |
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community. Ayton and Voth have also used Gay-Berne ellipsoids for |
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modelling large length-scale properties of lipid |
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bilayers.\cite{Ayton01} In its original form, the Gay-Berne potential |
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was a single site model for the interactions of rigid ellipsoidal |
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molecules.\cite{Gay81} It can be thought of as a modification of the |
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Gaussian overlap model originally described by Berne and |
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Pechukas.\cite{Berne72} The potential is constructed in the familiar |
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form of the Lennard-Jones function using orientation-dependent |
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$\sigma$ and $\epsilon$ parameters, |
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\begin{equation*} |
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V_{ij}({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, {\mathbf{\hat |
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r}_{ij}}) = 4\epsilon ({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, |
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|
{\mathbf{\hat r}_{ij}})\left[\left(\frac{\sigma_0}{r_{ij}-\sigma({\mathbf{\hat u}_i}, |
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|
{\mathbf{\hat u}_j}, {\mathbf{\hat r}_{ij}})+\sigma_0}\right)^{12} |
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|
-\left(\frac{\sigma_0}{r_{ij}-\sigma({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, |
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|
{\mathbf{\hat r}_{ij}})+\sigma_0}\right)^6\right] |
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\end{eqnarray*} |
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where $\sigma_0 = \sqrt 2\sigma_s$, and orietation-dependent range |
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parameter is given by |
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\begin{eqnarray*} |
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\sigma({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, {\mathbf{\hat r}_{ij}}) = |
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{\sigma_{0}} \left(1-\frac{1}{2}\chi\left[\frac{({\mathbf{\hat r}_{ij}} |
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\cdot {\mathbf{\hat u}_i} + {\mathbf{\hat r}_{ij}} \cdot {\mathbf{\hat |
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u}_j})^2}{1+\chi({\mathbf{\hat u}_i} \cdot {\mathbf{\hat u}_j})} + |
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\frac{({\mathbf{\hat r}_{ij}} \cdot {\mathbf{\hat u}_i} - {\mathbf{\hat r}_{ij}} |
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\cdot {\mathbf{\hat u}_j})^2}{1-\chi({\mathbf{\hat u}_i} \cdot |
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{\mathbf{\hat u}_j})} \right] \right)^{-\frac{1}{2}} |
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\end{eqnarray*} |
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and the strength anisotropy function is, |
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\begin{eqnarray*} |
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\epsilon ({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, {\mathbf{\hat r}_{ij}}) = |
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{\epsilon^\nu}({\mathbf{\hat u}_i}, {\mathbf{\hat |
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u}_j}){\epsilon'^\mu}({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, |
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{\mathbf{\hat r}_{ij}}) |
164 |
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\end{eqnarray*} |
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with $\nu$ and $\mu$ being adjustable exponent, and |
166 |
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$\epsilon({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j})$, |
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$\epsilon'({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, {\mathbf{\hat |
168 |
< |
r}_{ij}})$ defined as |
169 |
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\begin{eqnarray*} |
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\epsilon({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}) = |
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\epsilon_0\left[1-\chi^2({\mathbf{\hat u}_i} \cdot {\mathbf{\hat |
172 |
< |
u}_j})^2\right]^{-\frac{1}{2}} |
204 |
> |
\label{eq:gb} |
205 |
> |
\end{equation*} |
206 |
> |
|
207 |
> |
The range $(\sigma({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf |
208 |
> |
\hat{r}}_{ij}))$, and strength $(\epsilon({\bf \hat{u}}_{i},{\bf |
209 |
> |
\hat{u}}_{j},{\bf \hat{r}}_{ij}))$ parameters |
210 |
> |
are dependent on the relative orientations of the two molecules (${\bf |
211 |
> |
\hat{u}}_{i},{\bf \hat{u}}_{j}$) as well as the direction of the |
212 |
> |
intermolecular separation (${\bf \hat{r}}_{ij}$). $\sigma$ and |
213 |
> |
$\sigma_0$ are also governed by shape mixing and anisotropy variables, |
214 |
> |
\begin {eqnarray*} |
215 |
> |
\sigma_0 & = & \sqrt{d_i^2 + d_j^2} \\ \\ |
216 |
> |
\chi & = & \left[ \frac{\left( l_i^2 - d_i^2 \right) \left(l_j^2 - |
217 |
> |
d_j^2 \right)}{\left( l_j^2 + d_i^2 \right) \left(l_i^2 + |
218 |
> |
d_j^2 \right)}\right]^{1/2} \\ \\ |
219 |
> |
\alpha^2 & = & \left[ \frac{\left( l_i^2 - d_i^2 \right) \left(l_j^2 + |
220 |
> |
d_i^2 \right)}{\left( l_j^2 - d_j^2 \right) \left(l_i^2 + |
221 |
> |
d_j^2 \right)}\right]^{1/2}, |
222 |
|
\end{eqnarray*} |
223 |
< |
\begin{eqnarray*} |
224 |
< |
\epsilon'({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, {\mathbf{\hat r}_{ij}}) = |
225 |
< |
1-\frac{1}{2}\chi'\left[\frac{({\mathbf{\hat r}_{ij}} \cdot {\mathbf{\hat |
226 |
< |
u}_i} + {\mathbf{\hat r}_{ij}} \cdot {\mathbf{\hat |
227 |
< |
u}_j})^2}{1+\chi'({\mathbf{\hat u}_i} \cdot {\mathbf{\hat u}_j})} + |
228 |
< |
\frac{({\mathbf{\hat r}_{ij}} \cdot {\mathbf{\hat u}_i} - {\mathbf{\hat r}_{ij}} |
229 |
< |
\cdot {\mathbf{\hat u}_j})^2}{1-\chi'({\mathbf{\hat u}_i} \cdot |
230 |
< |
{\mathbf{\hat u}_j})} \right] |
223 |
> |
where $l$ and $d$ describe the length and width of each uniaxial |
224 |
> |
ellipsoid. These shape anisotropy parameters can then be used to |
225 |
> |
calculate the range function, |
226 |
> |
\begin{equation*} |
227 |
> |
\sigma({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf \hat{r}}_{ij}) = \sigma_{0} |
228 |
> |
\left[ 1- \left\{ \frac{ \chi \alpha^2 ({\bf \hat{u}}_i \cdot {\bf |
229 |
> |
\hat{r}}_{ij} ) + \chi \alpha^{-2} ({\bf \hat{u}}_j \cdot {\bf |
230 |
> |
\hat{r}}_{ij} ) - 2 \chi^2 ({\bf \hat{u}}_i \cdot {\bf |
231 |
> |
\hat{r}}_{ij} )({\bf \hat{u}}_j \cdot {\bf |
232 |
> |
\hat{r}}_{ij} ) ({\bf \hat{u}}_i \cdot {\bf \hat{u}}_j)}{1 - \chi^2 |
233 |
> |
\left({\bf \hat{u}}_i \cdot {\bf \hat{u}}_j\right)^2} \right\} |
234 |
> |
\right]^{-1/2} |
235 |
> |
\end{equation*} |
236 |
> |
|
237 |
> |
Gay-Berne ellipsoids also have an energy scaling parameter, |
238 |
> |
$\epsilon^s$, which describes the well depth for two identical |
239 |
> |
ellipsoids in a {\it side-by-side} configuration. Additionaly, a well |
240 |
> |
depth aspect ratio, $\epsilon^r = \epsilon^e / \epsilon^s$, describes |
241 |
> |
the ratio between the well depths in the {\it end-to-end} and |
242 |
> |
side-by-side configurations. As in the range parameter, a set of |
243 |
> |
mixing and anisotropy variables can be used to describe the well |
244 |
> |
depths for dissimilar particles, |
245 |
> |
\begin {eqnarray*} |
246 |
> |
\epsilon_0 & = & \sqrt{\epsilon^s_i * \epsilon^s_j} \\ \\ |
247 |
> |
\epsilon^r & = & \sqrt{\epsilon^r_i * \epsilon^r_j} \\ \\ |
248 |
> |
\chi' & = & \frac{1 - (\epsilon^r)^{1/\mu}}{1 + (\epsilon^r)^{1/\mu}} |
249 |
> |
\\ \\ |
250 |
> |
\alpha'^2 & = & \left[1 + (\epsilon^r)^{1/\mu}\right]^{-1} |
251 |
|
\end{eqnarray*} |
252 |
< |
the diameter dependent parameter $\chi$ is given by |
253 |
< |
\begin{eqnarray*} |
254 |
< |
\chi = \frac{({\sigma_s}^2 - |
255 |
< |
{\sigma_e}^2)}{({\sigma_s}^2 + {\sigma_e}^2)} |
256 |
< |
\end{eqnarray*} |
257 |
< |
and the well depth dependent parameter $\chi'$ is given by |
258 |
< |
\begin{eqnarray*} |
259 |
< |
\chi' = \frac{({\epsilon_s}^{\frac{1}{\mu}} - |
260 |
< |
{\epsilon_e}^{\frac{1}{\mu}})}{({\epsilon_s}^{\frac{1}{\mu}} + |
261 |
< |
{\epsilon_e}^{\frac{1}{\mu}})} |
262 |
< |
\end{eqnarray*} |
263 |
< |
$\sigma_s$ is the side-by-side width, and $\sigma_e$ is the end-to-end |
264 |
< |
length. $\epsilon_s$ is the side-by-side well depth, and $\epsilon_e$ |
265 |
< |
is the end-to-end well depth. For the interaction between |
266 |
< |
nonequivalent uniaxial ellipsoids (in this case, between spheres and |
267 |
< |
ellipsoids), the range parameter is generalized as\cite{Cleaver96} |
268 |
< |
\begin{eqnarray*} |
269 |
< |
\sigma({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, {\mathbf{\hat r}_{ij}}) = |
270 |
< |
{\sigma_{0}} \left(1-\frac{1}{2}\chi\left[\frac{(\alpha{\mathbf{\hat r}_{ij}} |
271 |
< |
\cdot {\mathbf{\hat u}_i} + \alpha^{-1}{\mathbf{\hat r}_{ij}} \cdot {\mathbf{\hat |
272 |
< |
u}_j})^2}{1+\chi({\mathbf{\hat u}_i} \cdot {\mathbf{\hat u}_j})} + |
273 |
< |
\frac{(\alpha{\mathbf{\hat r}_{ij}} \cdot {\mathbf{\hat u}_i} - \alpha^{-1}{\mathbf{\hat r}_{ij}} |
274 |
< |
\cdot {\mathbf{\hat u}_j})^2}{1-\chi({\mathbf{\hat u}_i} \cdot |
275 |
< |
{\mathbf{\hat u}_j})} \right] \right)^{-\frac{1}{2}} |
276 |
< |
\end{eqnarray*} |
208 |
< |
where $\alpha$ is given by |
209 |
< |
\begin{eqnarray*} |
210 |
< |
\alpha^2 = |
211 |
< |
\left[\frac{\left({\sigma_e}_i^2-{\sigma_s}_i^2\right)\left({\sigma_e}_j^2+{\sigma_s}_i^2\right)}{\left({\sigma_e}_j^2-{\sigma_s}_j^2\right)\left({\sigma_e}_i^2+{\sigma_s}_j^2\right)} |
212 |
< |
\right]^{\frac{1}{2}} |
213 |
< |
\end{eqnarray*} |
214 |
< |
the strength parameter is adjusted by the suggestion of |
215 |
< |
\cite{Cleaver96}. All potentials are truncated at $25$ \AA\ and |
216 |
< |
shifted at $22$ \AA. |
252 |
> |
The form of the strength function is somewhat complicated, |
253 |
> |
\begin {eqnarray*} |
254 |
> |
\epsilon({\bf \hat{u}}_{i}, {\bf \hat{u}}_{j},{\bf \hat{r}}_{ij}) & = & |
255 |
> |
\epsilon_{0} \epsilon_{1}^{\nu}({\bf \hat{u}}_{i}.{\bf \hat{u}}_{j}) |
256 |
> |
\epsilon_{2}^{\mu}({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf |
257 |
> |
\hat{r}}_{ij}) \\ \\ |
258 |
> |
\epsilon_{1}({\bf \hat{u}}_{i},{\bf \hat{u}}_{j}) & = & |
259 |
> |
\left[1-\chi^{2}({\bf \hat{u}}_{i}.{\bf |
260 |
> |
\hat{u}}_{j})^{2}\right]^{-1/2} \\ \\ |
261 |
> |
\epsilon_{2}({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf \hat{r}}_{ij}) & |
262 |
> |
= & |
263 |
> |
1 - \left\{ \frac{ \chi' \alpha'^2 ({\bf \hat{u}}_i \cdot {\bf |
264 |
> |
\hat{r}}_{ij} ) + \chi' \alpha'^{-2} ({\bf \hat{u}}_j \cdot {\bf |
265 |
> |
\hat{r}}_{ij} ) - 2 \chi'^2 ({\bf \hat{u}}_i \cdot {\bf |
266 |
> |
\hat{r}}_{ij} )({\bf \hat{u}}_j \cdot {\bf |
267 |
> |
\hat{r}}_{ij} ) ({\bf \hat{u}}_i \cdot {\bf \hat{u}}_j)}{1 - \chi'^2 |
268 |
> |
\left({\bf \hat{u}}_i \cdot {\bf \hat{u}}_j\right)^2} \right\}, |
269 |
> |
\end {eqnarray*} |
270 |
> |
although many of the quantities and derivatives are identical with |
271 |
> |
those obtained for the range parameter. Ref. \citen{Luckhurst90} |
272 |
> |
has a particularly good explanation of the choice of the Gay-Berne |
273 |
> |
parameters $\mu$ and $\nu$ for modeling liquid crystal molecules. An |
274 |
> |
excellent overview of the computational methods that can be used to |
275 |
> |
efficiently compute forces and torques for this potential can be found |
276 |
> |
in Ref. \citen{Golubkov06} |
277 |
|
|
278 |
< |
\section{Experiment} |
278 |
> |
The choices of parameters we have used in this study correspond to a |
279 |
> |
shape anisotropy of 3 for the chain portion of the molecule. In |
280 |
> |
principle, this could be varied to allow for modeling of longer or |
281 |
> |
shorter chain lipid molecules. For these prolate ellipsoids, we have: |
282 |
> |
\begin{equation} |
283 |
> |
\begin{array}{rcl} |
284 |
> |
d & < & l \\ |
285 |
> |
\epsilon^{r} & < & 1 |
286 |
> |
\end{array} |
287 |
> |
\end{equation} |
288 |
> |
A sketch of the various structural elements of our molecular-scale |
289 |
> |
lipid / solvent model is shown in figure \ref{fig:lipidModel}. The |
290 |
> |
actual parameters used in our simulations are given in table |
291 |
> |
\ref{tab:parameters}. |
292 |
> |
|
293 |
> |
\begin{figure}[htb] |
294 |
> |
\centering |
295 |
> |
\includegraphics[width=4in]{2lipidModel} |
296 |
> |
\caption{The parameters defining the behavior of the lipid |
297 |
> |
models. $l / d$ is the ratio of the head group to body diameter. |
298 |
> |
Molecular bodies had a fixed aspect ratio of 3.0. The solvent model |
299 |
> |
was a simplified 4-water bead ($\sigma_w \approx d$) that has been |
300 |
> |
used in other coarse-grained (DPD) simulations. The dipolar strength |
301 |
> |
(and the temperature and pressure) were the only other parameters that |
302 |
> |
were varied systematically.\label{fig:lipidModel}} |
303 |
> |
\end{figure} |
304 |
> |
|
305 |
> |
To take into account the permanent dipolar interactions of the |
306 |
> |
zwitterionic head groups, we place fixed dipole moments $\mu_{i}$ at |
307 |
> |
one end of the Gay-Berne particles. The dipoles are oriented at an |
308 |
> |
angle $\theta = \pi / 2$ relative to the major axis. These dipoles |
309 |
> |
are protected by a head ``bead'' with a range parameter which we have |
310 |
> |
varied between $1.20 d$ and $1.41 d$. The head groups interact with |
311 |
> |
each other using a combination of Lennard-Jones, |
312 |
> |
\begin{equation} |
313 |
> |
V_{ij}(r_{ij}) = 4\epsilon_h \left[\left(\frac{\sigma_h}{r_{ij}}\right)^{12} - |
314 |
> |
\left(\frac{\sigma_h}{r_{ij}}\right)^6\right], |
315 |
> |
\end{equation} |
316 |
> |
and dipole-dipole, |
317 |
> |
\begin{equation} |
318 |
> |
V_{ij}({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf |
319 |
> |
\hat{r}}_{ij})) = \frac{|\mu|^2}{4 \pi \epsilon_0 r_{ij}^3} |
320 |
> |
\left[ \hat{\bf u}_i \cdot \hat{\bf u}_j - 3 (\hat{\bf u}_i \cdot |
321 |
> |
\hat{\bf r}_{ij})(\hat{\bf u}_j \cdot \hat{\bf r}_{ij}) \right] |
322 |
> |
\end{equation} |
323 |
> |
potentials. |
324 |
> |
In these potentials, $\mathbf{\hat u}_i$ is the unit vector pointing |
325 |
> |
along dipole $i$ and $\mathbf{\hat r}_{ij}$ is the unit vector |
326 |
> |
pointing along the inter-dipole vector $\mathbf{r}_{ij}$. |
327 |
> |
|
328 |
> |
For the interaction between nonequivalent uniaxial ellipsoids (in this |
329 |
> |
case, between spheres and ellipsoids), the spheres are treated as |
330 |
> |
ellipsoids with an aspect ratio of 1 ($d = l$) and with an well depth |
331 |
> |
ratio ($\epsilon^r$) of 1 ($\epsilon^e = \epsilon^s$). The form of |
332 |
> |
the Gay-Berne potential we are using was generalized by Cleaver {\it |
333 |
> |
et al.} and is appropriate for dissimilar uniaxial |
334 |
> |
ellipsoids.\cite{Cleaver96} |
335 |
> |
|
336 |
> |
The solvent model in our simulations is identical to one used by |
337 |
> |
Marrink {\it et al.} in their dissipative particle dynamics (DPD) |
338 |
> |
simulation of lipid bilayers.\cite{Marrink04} This solvent bead is a single |
339 |
> |
site that represents four water molecules (m = 72 amu) and has |
340 |
> |
comparable density and diffusive behavior to liquid water. However, |
341 |
> |
since there are no electrostatic sites on these beads, this solvent |
342 |
> |
model cannot replicate the dielectric properties of water. |
343 |
> |
\begin{table*} |
344 |
> |
\begin{minipage}{\linewidth} |
345 |
> |
\begin{center} |
346 |
> |
\caption{Potential parameters used for molecular-scale coarse-grained |
347 |
> |
lipid simulations} |
348 |
> |
\begin{tabular}{llccc} |
349 |
> |
\hline |
350 |
> |
& & Head & Chain & Solvent \\ |
351 |
> |
\hline |
352 |
> |
$d$ (\AA) & & varied & 4.6 & 4.7 \\ |
353 |
> |
$l$ (\AA) & & $= d$ & 13.8 & 4.7 \\ |
354 |
> |
$\epsilon^s$ (kcal/mol) & & 0.185 & 1.0 & 0.8 \\ |
355 |
> |
$\epsilon_r$ (well-depth aspect ratio)& & 1 & 0.2 & 1 \\ |
356 |
> |
$m$ (amu) & & 196 & 760 & 72.06 \\ |
357 |
> |
$\overleftrightarrow{\mathsf I}$ (amu \AA$^2$) & & & & \\ |
358 |
> |
\multicolumn{2}c{$I_{xx}$} & 1125 & 45000 & N/A \\ |
359 |
> |
\multicolumn{2}c{$I_{yy}$} & 1125 & 45000 & N/A \\ |
360 |
> |
\multicolumn{2}c{$I_{zz}$} & 0 & 9000 & N/A \\ |
361 |
> |
$\mu$ (Debye) & & varied & 0 & 0 \\ |
362 |
> |
\end{tabular} |
363 |
> |
\label{tab:parameters} |
364 |
> |
\end{center} |
365 |
> |
\end{minipage} |
366 |
> |
\end{table*} |
367 |
> |
|
368 |
> |
A switching function has been applied to all potentials to smoothly |
369 |
> |
turn off the interactions between a range of $22$ and $25$ \AA. |
370 |
> |
|
371 |
> |
The parameters that were systematically varied in this study were the |
372 |
> |
size of the head group ($\sigma_h$), the strength of the dipole moment |
373 |
> |
($\mu$), and the temperature of the system. Values for $\sigma_h$ |
374 |
> |
ranged from 5.5 \AA\ to 6.5 \AA\ . If the width of the tails is |
375 |
> |
taken to be the unit of length, these head groups correspond to a |
376 |
> |
range from $1.2 d$ to $1.41 d$. Since the solvent beads are nearly |
377 |
> |
identical in diameter to the tail ellipsoids, all distances that |
378 |
> |
follow will be measured relative to this unit of distance. |
379 |
> |
|
380 |
> |
\section{Experimental Methodology} |
381 |
|
\label{sec:experiment} |
382 |
|
|
383 |
< |
To make the simulations less expensive and to observe long-time |
384 |
< |
behavior of the lipid membranes, all simulations were started from two |
385 |
< |
separate monolayers in the vaccum with $x-y$ anisotropic pressure |
383 |
> |
To create unbiased bilayers, all simulations were started from two |
384 |
> |
perfectly flat monolayers separated by a 26 \AA\ gap between the |
385 |
> |
molecular bodies of the upper and lower leaves. The separated |
386 |
> |
monolayers were evolved in a vaccum with $x-y$ anisotropic pressure |
387 |
|
coupling. The length of $z$ axis of the simulations was fixed and a |
388 |
|
constant surface tension was applied to enable real fluctuations of |
389 |
< |
the bilayer. Periodic boundaries were used. There were $480-720$ lipid |
390 |
< |
molecules in the simulations depending on the size of the head |
391 |
< |
beads. All the simulations were equlibrated for $100$ ns at $300$ |
392 |
< |
K. The resulting structures were solvated in water ($6$ DPD |
393 |
< |
water/lipid molecule). These configurations were relaxed for another |
231 |
< |
$30$ ns relaxation. All simulations with water were carried out at |
232 |
< |
constant pressure ($P=1$ atm) by $3$D anisotropic coupling, and |
233 |
< |
constant surface tension ($\gamma=0.015$). Given the absence of fast |
234 |
< |
degrees of freedom in this model, a timestep of $50$ fs was |
235 |
< |
utilized. Simulations were performed by using OOPSE |
236 |
< |
package\cite{Meineke05}. |
389 |
> |
the bilayer. Periodic boundary conditions were used, and $480-720$ |
390 |
> |
lipid molecules were present in the simulations, depending on the size |
391 |
> |
of the head beads. In all cases, the two monolayers spontaneously |
392 |
> |
collapsed into bilayer structures within 100 ps. Following this |
393 |
> |
collapse, all systems were equlibrated for $100$ ns at $300$ K. |
394 |
|
|
395 |
< |
\section{Results and Analysis} |
395 |
> |
The resulting bilayer structures were then solvated at a ratio of $6$ |
396 |
> |
solvent beads (24 water molecules) per lipid. These configurations |
397 |
> |
were then equilibrated for another $30$ ns. All simulations utilizing |
398 |
> |
the solvent were carried out at constant pressure ($P=1$ atm) with |
399 |
> |
$3$D anisotropic coupling, and constant surface tension |
400 |
> |
($\gamma=0.015$ UNIT). Given the absence of fast degrees of freedom in |
401 |
> |
this model, a timestep of $50$ fs was utilized with excellent energy |
402 |
> |
conservation. Data collection for structural properties of the |
403 |
> |
bilayers was carried out during a final 5 ns run following the solvent |
404 |
> |
equilibration. All simulations were performed using the OOPSE |
405 |
> |
molecular modeling program.\cite{Meineke05} |
406 |
> |
|
407 |
> |
\section{Results} |
408 |
|
\label{sec:results} |
409 |
|
|
410 |
|
Snapshots in Figure \ref{fig:phaseCartoon} show that the membrane is |
411 |
< |
more corrugated increasing size of the head groups. The surface is |
412 |
< |
nearly flat when $\sigma_h=1.20\sigma_0$. With |
413 |
< |
$\sigma_h=1.28\sigma_0$, although the surface is still flat, the |
414 |
< |
bilayer starts to splay inward; the upper leaf of the bilayer is |
415 |
< |
connected to the lower leaf with an interdigitated line defect. Two |
416 |
< |
periodicities with $100$ \AA\ width were observed in the |
417 |
< |
simulation. This structure is very similiar to the structure observed |
418 |
< |
by de Vries and Lenz {\it et al.}. The same basic structure is also |
419 |
< |
observed when $\sigma_h=1.41\sigma_0$, but the wavelength of the |
420 |
< |
surface corrugations depends sensitively on the size of the ``head'' |
421 |
< |
beads. From the undulation spectrum, the corrugation is clearly |
253 |
< |
non-thermal. |
411 |
> |
more corrugated with increasing size of the head groups. The surface |
412 |
> |
is nearly flat when $\sigma_h=1.20 d$. With $\sigma_h=1.28 d$, |
413 |
> |
although the surface is still flat, the bilayer starts to splay |
414 |
> |
inward; the upper leaf of the bilayer is connected to the lower leaf |
415 |
> |
with an interdigitated line defect. Two periodicities with $100$ \AA\ |
416 |
> |
wavelengths were observed in the simulation. This structure is very |
417 |
> |
similiar to the structure observed by de Vries and Lenz {\it et |
418 |
> |
al.}. The same basic structure is also observed when $\sigma_h=1.41 |
419 |
> |
d$, but the wavelength of the surface corrugations depends sensitively |
420 |
> |
on the size of the ``head'' beads. From the undulation spectrum, the |
421 |
> |
corrugation is clearly non-thermal. |
422 |
|
\begin{figure}[htb] |
423 |
|
\centering |
424 |
< |
\includegraphics[width=\linewidth]{phaseCartoon} |
424 |
> |
\includegraphics[width=4in]{phaseCartoon} |
425 |
|
\caption{A sketch to discribe the structure of the phases observed in |
426 |
|
our simulations.\label{fig:phaseCartoon}} |
427 |
|
\end{figure} |
428 |
|
|
429 |
< |
When $\sigma_h=1.35\sigma_0$, we observed another corrugated surface |
430 |
< |
morphology. This structure is different from the asymmetric rippled |
429 |
> |
When $\sigma_h=1.35 d$, we observed another corrugated surface |
430 |
> |
morphology. This structure is different from the asymmetric rippled |
431 |
|
surface; there is no interdigitation between the upper and lower |
432 |
|
leaves of the bilayer. Each leaf of the bilayer is broken into several |
433 |
|
hemicylinderical sections, and opposite leaves are fitted together |
434 |
|
much like roof tiles. Unlike the surface in which the upper |
435 |
|
hemicylinder is always interdigitated on the leading or trailing edge |
436 |
< |
of lower hemicylinder, the symmetric ripple has no prefered direction. |
437 |
< |
The corresponding cartoons are shown in Figure |
436 |
> |
of lower hemicylinder, this ``symmetric'' ripple has no prefered |
437 |
> |
direction. The corresponding structures are shown in Figure |
438 |
|
\ref{fig:phaseCartoon} for elucidation of the detailed structures of |
439 |
< |
different phases. Figure \ref{fig:phaseCartoon} (a) is the flat phase, |
440 |
< |
(b) is the asymmetric ripple phase corresponding to the lipid |
441 |
< |
organization when $\sigma_h=1.28\sigma_0$ and $\sigma_h=1.41\sigma_0$, |
442 |
< |
and (c) is the symmetric ripple phase observed when |
443 |
< |
$\sigma_h=1.35\sigma_0$. In symmetric ripple phase, the bilayer is |
444 |
< |
continuous everywhere on the whole membrane, however, in asymmetric |
445 |
< |
ripple phase, the bilayer is intermittent domains connected by thin |
446 |
< |
interdigitated monolayer which consists of upper and lower leaves of |
279 |
< |
the bilayer. |
439 |
> |
different phases. The top panel in figure \ref{fig:phaseCartoon} is |
440 |
> |
the flat phase, the middle panel shows the asymmetric ripple phase |
441 |
> |
corresponding to $\sigma_h = 1.41 d$ and the lower panel shows the |
442 |
> |
symmetric ripple phase observed when $\sigma_h=1.35 d$. In the |
443 |
> |
symmetric ripple, the bilayer is continuous over the whole membrane, |
444 |
> |
however, in asymmetric ripple phase, the bilayer domains are connected |
445 |
> |
by thin interdigitated monolayers that share molecules between the |
446 |
> |
upper and lower leaves. |
447 |
|
\begin{table*} |
448 |
|
\begin{minipage}{\linewidth} |
449 |
|
\begin{center} |
450 |
< |
\caption{} |
450 |
> |
\caption{Phases, ripple wavelengths and amplitudes observed as a |
451 |
> |
function of the ratio between the head beads and the diameters of the |
452 |
> |
tails. All lengths are normalized to the diameter of the tail |
453 |
> |
ellipsoids.} |
454 |
|
\begin{tabular}{lccc} |
455 |
|
\hline |
456 |
< |
$\sigma_h/\sigma_0$ & type of phase & $\lambda/\sigma_0$ & $A/\sigma_0$\\ |
456 |
> |
$\sigma_h / d$ & type of phase & $\lambda / d$ & $A / d$\\ |
457 |
|
\hline |
458 |
|
1.20 & flat & N/A & N/A \\ |
459 |
< |
1.28 & asymmetric flat & 21.7 & N/A \\ |
459 |
> |
1.28 & asymmetric ripple or flat & 21.7 & N/A \\ |
460 |
|
1.35 & symmetric ripple & 17.2 & 2.2 \\ |
461 |
|
1.41 & asymmetric ripple & 15.4 & 1.5 \\ |
462 |
|
\end{tabular} |
465 |
|
\end{minipage} |
466 |
|
\end{table*} |
467 |
|
|
468 |
< |
The membrane structures and the reduced wavelength $\lambda/\sigma_0$, |
469 |
< |
reduced amplitude $A/\sigma_0$ of the ripples are summerized in Table |
470 |
< |
\ref{tab:property}. The wavelength range is $15~21$ and the amplitude |
471 |
< |
is $1.5$ for asymmetric ripple and $2.2$ for symmetric ripple. These |
472 |
< |
values are consistent to the experimental results. Note, the |
473 |
< |
amplitudes are underestimated without the melted tails in our |
474 |
< |
simulations. |
468 |
> |
The membrane structures and the reduced wavelength $\lambda / d$, |
469 |
> |
reduced amplitude $A / d$ of the ripples are summarized in Table |
470 |
> |
\ref{tab:property}. The wavelength range is $15~21$ molecular bodies |
471 |
> |
and the amplitude is $1.5$ molecular bodies for asymmetric ripple and |
472 |
> |
$2.2$ for symmetric ripple. These values are consistent to the |
473 |
> |
experimental results. Note, that given the lack of structural freedom |
474 |
> |
in the tails of our model lipids, the amplitudes observed from these |
475 |
> |
simulations are likely to underestimate of the true amplitudes. |
476 |
|
|
477 |
< |
The $P_2$ order paramters (for molecular bodies and head group |
478 |
< |
dipoles) have been calculated to clarify the ordering in these phases |
479 |
< |
quantatively. $P_2=1$ means a perfectly ordered structure, and $P_2=0$ |
480 |
< |
implies orientational randomization. Figure \ref{fig:rP2} shows the |
481 |
< |
$P_2$ order paramter of the dipoles on head group rising with |
482 |
< |
increasing head group size. When the heads of the lipid molecules are |
483 |
< |
small, the membrane is flat. The dipolar ordering is essentially |
484 |
< |
frustrated on orientational ordering in this circumstance. Another |
485 |
< |
reason is that the lipids can move independently in each monolayer, it |
486 |
< |
is not nessasory for the direction of dipoles on one leaf is |
487 |
< |
consistant to another layer, which makes total order parameter is |
488 |
< |
relatively low. With increasing head group size, the surface is |
318 |
< |
corrugated, and dipoles do not move as freely on the |
319 |
< |
surface. Therefore, the translational freedom of lipids in one layer |
320 |
< |
is dependent upon the position of lipids in another layer, as a |
321 |
< |
result, the symmetry of the dipoles on head group in one layer is tied |
322 |
< |
to the symmetry in the other layer. Furthermore, as the membrane |
323 |
< |
deforms from two to three dimensions due to the corrugation, the |
324 |
< |
symmetry of the ordering for the dipoles embedded on each leaf is |
325 |
< |
broken. The dipoles then self-assemble in a head-tail configuration, |
326 |
< |
and the order parameter increases dramaticaly. However, the total |
327 |
< |
polarization of the system is still close to zero. This is strong |
328 |
< |
evidence that the corrugated structure is an antiferroelectric |
329 |
< |
state. The orientation of the dipolar is always perpendicular to the |
330 |
< |
ripple wave vector. These results are consistent with our previous |
331 |
< |
study on dipolar membranes. |
477 |
> |
\begin{figure}[htb] |
478 |
> |
\centering |
479 |
> |
\includegraphics[width=4in]{topDown} |
480 |
> |
\caption{Top views of the flat (upper), asymmetric ripple (middle), |
481 |
> |
and symmetric ripple (lower) phases. Note that the head-group dipoles |
482 |
> |
have formed head-to-tail chains in all three of these phases, but in |
483 |
> |
the two rippled phases, the dipolar chains are all aligned |
484 |
> |
{\it perpendicular} to the direction of the ripple. The flat membrane |
485 |
> |
has multiple point defects in the dipolar orientational ordering, and |
486 |
> |
the dipolar ordering on the lower leaf of the bilayer can be in a |
487 |
> |
different direction from the upper leaf.\label{fig:topView}} |
488 |
> |
\end{figure} |
489 |
|
|
490 |
< |
The ordering of the tails is essentially opposite to the ordering of |
491 |
< |
the dipoles on head group. The $P_2$ order parameter decreases with |
492 |
< |
increasing head size. This indicates the surface is more curved with |
493 |
< |
larger head groups. When the surface is flat, all tails are pointing |
494 |
< |
in the same direction; in this case, all tails are parallel to the |
495 |
< |
normal of the surface,(making this structure remindcent of the |
496 |
< |
$L_{\beta}$ phase. Increasing the size of the heads, results in |
490 |
> |
The principal method for observing orientational ordering in dipolar |
491 |
> |
or liquid crystalline systems is the $P_2$ order parameter (defined |
492 |
> |
as $1.5 \times \lambda_{max}$, where $\lambda_{max}$ is the largest |
493 |
> |
eigenvalue of the matrix, |
494 |
> |
\begin{equation} |
495 |
> |
{\mathsf{S}} = \frac{1}{N} \sum_i \left( |
496 |
> |
\begin{array}{ccc} |
497 |
> |
u^{x}_i u^{x}_i-\frac{1}{3} & u^{x}_i u^{y}_i & u^{x}_i u^{z}_i \\ |
498 |
> |
u^{y}_i u^{x}_i & u^{y}_i u^{y}_i -\frac{1}{3} & u^{y}_i u^{z}_i \\ |
499 |
> |
u^{z}_i u^{x}_i & u^{z}_i u^{y}_i & u^{z}_i u^{z}_i -\frac{1}{3} |
500 |
> |
\end{array} \right). |
501 |
> |
\label{eq:opmatrix} |
502 |
> |
\end{equation} |
503 |
> |
Here $u^{\alpha}_i$ is the $\alpha=x,y,z$ component of the unit vector |
504 |
> |
for molecule $i$. (Here, $\hat{\bf u}_i$ can refer either to the |
505 |
> |
principal axis of the molecular body or to the dipole on the head |
506 |
> |
group of the molecule.) $P_2$ will be $1.0$ for a perfectly-ordered |
507 |
> |
system and near $0$ for a randomized system. Note that this order |
508 |
> |
parameter is {\em not} equal to the polarization of the system. For |
509 |
> |
example, the polarization of a perfect anti-ferroelectric arrangement |
510 |
> |
of point dipoles is $0$, but $P_2$ for the same system is $1$. The |
511 |
> |
eigenvector of $\mathsf{S}$ corresponding to the largest eigenvalue is |
512 |
> |
familiar as the director axis, which can be used to determine a |
513 |
> |
privileged axis for an orientationally-ordered system. Since the |
514 |
> |
molecular bodies are perpendicular to the head group dipoles, it is |
515 |
> |
possible for the director axes for the molecular bodies and the head |
516 |
> |
groups to be completely decoupled from each other. |
517 |
> |
|
518 |
> |
Figure \ref{fig:topView} shows snapshots of bird's-eye views of the |
519 |
> |
flat ($\sigma_h = 1.20 d$) and rippled ($\sigma_h = 1.41, 1.35 d$) |
520 |
> |
bilayers. The directions of the dipoles on the head groups are |
521 |
> |
represented with two colored half spheres: blue (phosphate) and yellow |
522 |
> |
(amino). For flat bilayers, the system exhibits signs of |
523 |
> |
orientational frustration; some disorder in the dipolar head-to-tail |
524 |
> |
chains is evident with kinks visible at the edges between differently |
525 |
> |
ordered domains. The lipids can also move independently of lipids in |
526 |
> |
the opposing leaf, so the ordering of the dipoles on one leaf is not |
527 |
> |
necessarily consistent with the ordering on the other. These two |
528 |
> |
factors keep the total dipolar order parameter relatively low for the |
529 |
> |
flat phases. |
530 |
> |
|
531 |
> |
With increasing head group size, the surface becomes corrugated, and |
532 |
> |
the dipoles cannot move as freely on the surface. Therefore, the |
533 |
> |
translational freedom of lipids in one layer is dependent upon the |
534 |
> |
position of the lipids in the other layer. As a result, the ordering of |
535 |
> |
the dipoles on head groups in one leaf is correlated with the ordering |
536 |
> |
in the other leaf. Furthermore, as the membrane deforms due to the |
537 |
> |
corrugation, the symmetry of the allowed dipolar ordering on each leaf |
538 |
> |
is broken. The dipoles then self-assemble in a head-to-tail |
539 |
> |
configuration, and the dipolar order parameter increases dramatically. |
540 |
> |
However, the total polarization of the system is still close to zero. |
541 |
> |
This is strong evidence that the corrugated structure is an |
542 |
> |
antiferroelectric state. It is also notable that the head-to-tail |
543 |
> |
arrangement of the dipoles is always observed in a direction |
544 |
> |
perpendicular to the wave vector for the surface corrugation. This is |
545 |
> |
a similar finding to what we observed in our earlier work on the |
546 |
> |
elastic dipolar membranes.\cite{Sun2007} |
547 |
> |
|
548 |
> |
The $P_2$ order parameters (for both the molecular bodies and the head |
549 |
> |
group dipoles) have been calculated to quantify the ordering in these |
550 |
> |
phases. Figure \ref{fig:rP2} shows that the $P_2$ order parameter for |
551 |
> |
the head-group dipoles increases with increasing head group size. When |
552 |
> |
the heads of the lipid molecules are small, the membrane is nearly |
553 |
> |
flat. Since the in-plane packing is essentially a close packing of the |
554 |
> |
head groups, the head dipoles exhibit frustration in their |
555 |
> |
orientational ordering. |
556 |
> |
|
557 |
> |
The ordering trends for the tails are essentially opposite to the |
558 |
> |
ordering of the head group dipoles. The tail $P_2$ order parameter |
559 |
> |
{\it decreases} with increasing head size. This indicates that the |
560 |
> |
surface is more curved with larger head / tail size ratios. When the |
561 |
> |
surface is flat, all tails are pointing in the same direction (normal |
562 |
> |
to the bilayer surface). This simplified model appears to be |
563 |
> |
exhibiting a smectic A fluid phase, similar to the real $L_{\beta}$ |
564 |
> |
phase. We have not observed a smectic C gel phase ($L_{\beta'}$) for |
565 |
> |
this model system. Increasing the size of the heads results in |
566 |
|
rapidly decreasing $P_2$ ordering for the molecular bodies. |
567 |
+ |
|
568 |
|
\begin{figure}[htb] |
569 |
|
\centering |
570 |
|
\includegraphics[width=\linewidth]{rP2} |
571 |
< |
\caption{The $P_2$ order parameter as a funtion of the ratio of |
572 |
< |
$\sigma_h$ to $\sigma_0$.\label{fig:rP2}} |
571 |
> |
\caption{The $P_2$ order parameters for head groups (circles) and |
572 |
> |
molecular bodies (squares) as a function of the ratio of head group |
573 |
> |
size ($\sigma_h$) to the width of the molecular bodies ($d$). \label{fig:rP2}} |
574 |
|
\end{figure} |
575 |
|
|
576 |
< |
We studied the effects of the interactions between head groups on the |
577 |
< |
structure of lipid bilayer by changing the strength of the dipole. |
578 |
< |
Figure \ref{fig:sP2} shows how the $P_2$ order parameter changes with |
579 |
< |
increasing strength of the dipole. Generally the dipoles on the head |
580 |
< |
group are more ordered by increase in the strength of the interaction |
581 |
< |
between heads and are more disordered by decreasing the interaction |
582 |
< |
stength. When the interaction between the heads is weak enough, the |
583 |
< |
bilayer structure does not persist; all lipid molecules are solvated |
584 |
< |
directly in the water. The critial value of the strength of the dipole |
585 |
< |
depends on the head size. The perfectly flat surface melts at $5$ |
586 |
< |
debye, the asymmetric rippled surfaces melt at $8$ debye, the |
587 |
< |
symmetric rippled surfaces melt at $10$ debye. The ordering of the |
588 |
< |
tails is the same as the ordering of the dipoles except for the flat |
589 |
< |
phase. Since the surface is already perfect flat, the order parameter |
590 |
< |
does not change much until the strength of the dipole is $15$ |
591 |
< |
debye. However, the order parameter decreases quickly when the |
592 |
< |
strength of the dipole is further increased. The head groups of the |
593 |
< |
lipid molecules are brought closer by stronger interactions between |
594 |
< |
them. For a flat surface, a large amount of free volume between the |
595 |
< |
head groups is available, but when the head groups are brought closer, |
596 |
< |
the tails will splay outward, forming an inverse micelle. For rippled |
597 |
< |
surfaces, there is less free volume available between the head |
598 |
< |
groups. Therefore there is little effect on the structure of the |
599 |
< |
membrane due to increasing dipolar strength. Unlike other systems that |
600 |
< |
melt directly when the interaction is weak enough, for |
601 |
< |
$\sigma_h=1.41\sigma_0$, part of the membrane melts into itself |
602 |
< |
first. The upper leaf of the bilayer becomes totally interdigitated |
603 |
< |
with the lower leaf. This is different behavior than what is exhibited |
604 |
< |
with the interdigitated lines in the rippled phase where only one |
605 |
< |
interdigitated line connects the two leaves of bilayer. |
576 |
> |
In addition to varying the size of the head groups, we studied the |
577 |
> |
effects of the interactions between head groups on the structure of |
578 |
> |
lipid bilayer by changing the strength of the dipoles. Figure |
579 |
> |
\ref{fig:sP2} shows how the $P_2$ order parameter changes with |
580 |
> |
increasing strength of the dipole. Generally, the dipoles on the head |
581 |
> |
groups become more ordered as the strength of the interaction between |
582 |
> |
heads is increased and become more disordered by decreasing the |
583 |
> |
interaction stength. When the interaction between the heads becomes |
584 |
> |
too weak, the bilayer structure does not persist; all lipid molecules |
585 |
> |
become dispersed in the solvent (which is non-polar in this |
586 |
> |
molecular-scale model). The critial value of the strength of the |
587 |
> |
dipole depends on the size of the head groups. The perfectly flat |
588 |
> |
surface becomes unstable below $5$ Debye, while the rippled |
589 |
> |
surfaces melt at $8$ Debye (asymmetric) or $10$ Debye (symmetric). |
590 |
> |
|
591 |
> |
The ordering of the tails mirrors the ordering of the dipoles {\it |
592 |
> |
except for the flat phase}. Since the surface is nearly flat in this |
593 |
> |
phase, the order parameters are only weakly dependent on dipolar |
594 |
> |
strength until it reaches $15$ Debye. Once it reaches this value, the |
595 |
> |
head group interactions are strong enough to pull the head groups |
596 |
> |
close to each other and distort the bilayer structure. For a flat |
597 |
> |
surface, a substantial amount of free volume between the head groups |
598 |
> |
is normally available. When the head groups are brought closer by |
599 |
> |
dipolar interactions, the tails are forced to splay outward, forming |
600 |
> |
first curved bilayers, and then inverted micelles. |
601 |
> |
|
602 |
> |
When $\sigma_h=1.28 d$, the $P_2$ order parameter decreases slightly |
603 |
> |
when the strength of the dipole is increased above $16$ debye. For |
604 |
> |
rippled bilayers, there is less free volume available between the head |
605 |
> |
groups. Therefore increasing dipolar strength weakly influences the |
606 |
> |
structure of the membrane. However, the increase in the body $P_2$ |
607 |
> |
order parameters implies that the membranes are being slightly |
608 |
> |
flattened due to the effects of increasing head-group attraction. |
609 |
> |
|
610 |
> |
A very interesting behavior takes place when the head groups are very |
611 |
> |
large relative to the molecular bodies ($\sigma_h = 1.41 d$) and the |
612 |
> |
dipolar strength is relatively weak ($\mu < 9$ Debye). In this case, |
613 |
> |
the two leaves of the bilayer become totally interdigitated with each |
614 |
> |
other in large patches of the membrane. With higher dipolar |
615 |
> |
strength, the interdigitation is limited to single lines that run |
616 |
> |
through the bilayer in a direction perpendicular to the ripple wave |
617 |
> |
vector. |
618 |
> |
|
619 |
|
\begin{figure}[htb] |
620 |
|
\centering |
621 |
|
\includegraphics[width=\linewidth]{sP2} |
622 |
< |
\caption{The $P_2$ order parameter as a funtion of the strength of the |
623 |
< |
dipole.\label{fig:sP2}} |
622 |
> |
\caption{The $P_2$ order parameters for head group dipoles (a) and |
623 |
> |
molecular bodies (b) as a function of the strength of the dipoles. |
624 |
> |
These order parameters are shown for four values of the head group / |
625 |
> |
molecular width ratio ($\sigma_h / d$). \label{fig:sP2}} |
626 |
|
\end{figure} |
627 |
|
|
628 |
< |
Figure \ref{fig:tP2} shows the dependence of the order parameter on |
629 |
< |
temperature. The behavior of the $P_2$ order paramter is |
630 |
< |
straightforward. Systems are more ordered at low temperature, and more |
631 |
< |
disordered at high temperatures. When the temperature is high enough, |
632 |
< |
the membranes are instable. Since our model lacks the detailed |
633 |
< |
information on lipid tails, we can not simulate the fluid phase with |
634 |
< |
melted fatty acid chains. Moreover, the formation of the tilted |
635 |
< |
$L_{\beta'}$ phase also depends on the organization of fatty groups on |
636 |
< |
tails. |
628 |
> |
Figure \ref{fig:tP2} shows the dependence of the order parameters on |
629 |
> |
temperature. As expected, systems are more ordered at low |
630 |
> |
temperatures, and more disordered at high temperatures. All of the |
631 |
> |
bilayers we studied can become unstable if the temperature becomes |
632 |
> |
high enough. The only interesting feature of the temperature |
633 |
> |
dependence is in the flat surfaces ($\sigma_h=1.20 d$ and |
634 |
> |
$\sigma_h=1.28 d$). Here, when the temperature is increased above |
635 |
> |
$310$K, there is enough jostling of the head groups to allow the |
636 |
> |
dipolar frustration to resolve into more ordered states. This results |
637 |
> |
in a slight increase in the $P_2$ order parameter above this |
638 |
> |
temperature. |
639 |
> |
|
640 |
> |
For the rippled surfaces ($\sigma_h=1.35 d$ and $\sigma_h=1.41 d$), |
641 |
> |
there is a slightly increased orientational ordering in the molecular |
642 |
> |
bodies above $290$K. Since our model lacks the detailed information |
643 |
> |
about the behavior of the lipid tails, this is the closest the model |
644 |
> |
can come to depicting the ripple ($P_{\beta'}$) to fluid |
645 |
> |
($L_{\alpha}$) phase transition. What we are observing is a |
646 |
> |
flattening of the rippled structures made possible by thermal |
647 |
> |
expansion of the tightly-packed head groups. The lack of detailed |
648 |
> |
chain configurations also makes it impossible for this model to depict |
649 |
> |
the ripple to gel ($L_{\beta'}$) phase transition. |
650 |
> |
|
651 |
|
\begin{figure}[htb] |
652 |
|
\centering |
653 |
|
\includegraphics[width=\linewidth]{tP2} |
654 |
< |
\caption{The $P_2$ order parameter as a funtion of |
655 |
< |
temperature.\label{fig:tP2}} |
654 |
> |
\caption{The $P_2$ order parameters for head group dipoles (a) and |
655 |
> |
molecular bodies (b) as a function of temperature. |
656 |
> |
These order parameters are shown for four values of the head group / |
657 |
> |
molecular width ratio ($\sigma_h / d$).\label{fig:tP2}} |
658 |
|
\end{figure} |
659 |
|
|
660 |
|
\section{Discussion} |
661 |
|
\label{sec:discussion} |
662 |
|
|
663 |
+ |
The ripple phases have been observed in our molecular dynamic |
664 |
+ |
simulations using a simple molecular lipid model. The lipid model |
665 |
+ |
consists of an anisotropic interacting dipolar head group and an |
666 |
+ |
ellipsoid shape tail. According to our simulations, the explanation of |
667 |
+ |
the formation for the ripples are originated in the size mismatch |
668 |
+ |
between the head groups and the tails. The ripple phases are only |
669 |
+ |
observed in the studies using larger head group lipid models. However, |
670 |
+ |
there is a mismatch betweent the size of the head groups and the size |
671 |
+ |
of the tails in the simulations of the flat surface. This indicates |
672 |
+ |
the competition between the anisotropic dipolar interaction and the |
673 |
+ |
packing of the tails also plays a major role for formation of the |
674 |
+ |
ripple phase. The larger head groups provide more free volume for the |
675 |
+ |
tails, while these hydrophobic ellipsoids trying to be close to each |
676 |
+ |
other, this gives the origin of the spontanous curvature of the |
677 |
+ |
surface, which is believed as the beginning of the ripple phases. The |
678 |
+ |
lager head groups cause the spontanous curvature inward for both of |
679 |
+ |
leaves of the bilayer. This results in a steric strain when the tails |
680 |
+ |
of two leaves too close to each other. The membrane has to be broken |
681 |
+ |
to release this strain. There are two ways to arrange these broken |
682 |
+ |
curvatures: symmetric and asymmetric ripples. Both of the ripple |
683 |
+ |
phases have been observed in our studies. The difference between these |
684 |
+ |
two ripples is that the bilayer is continuum in the symmetric ripple |
685 |
+ |
phase and is disrupt in the asymmetric ripple phase. |
686 |
+ |
|
687 |
+ |
Dipolar head groups are the key elements for the maintaining of the |
688 |
+ |
bilayer structure. The lipids are solvated in water when lowering the |
689 |
+ |
the strength of the dipole on the head groups. The long range |
690 |
+ |
orientational ordering of the dipoles can be achieved by forming the |
691 |
+ |
ripples, although the dipoles are likely to form head-to-tail |
692 |
+ |
configurations even in flat surface, the frustration prevents the |
693 |
+ |
formation of the long range orientational ordering for dipoles. The |
694 |
+ |
corrugation of the surface breaks the frustration and stablizes the |
695 |
+ |
long range oreintational ordering for the dipoles in the head groups |
696 |
+ |
of the lipid molecules. Many rows of the head-to-tail dipoles are |
697 |
+ |
parallel to each other and adopt the antiferroelectric state as a |
698 |
+ |
whole. This is the first time the organization of the head groups in |
699 |
+ |
ripple phases of the lipid bilayer has been addressed. |
700 |
+ |
|
701 |
+ |
The most important prediction we can make using the results from this |
702 |
+ |
simple model is that if dipolar ordering is driving the surface |
703 |
+ |
corrugation, the wave vectors for the ripples should always found to |
704 |
+ |
be {\it perpendicular} to the dipole director axis. This prediction |
705 |
+ |
should suggest experimental designs which test whether this is really |
706 |
+ |
true in the phosphatidylcholine $P_{\beta'}$ phases. The dipole |
707 |
+ |
director axis should also be easily computable for the all-atom and |
708 |
+ |
coarse-grained simulations that have been published in the literature. |
709 |
+ |
|
710 |
+ |
Although our model is simple, it exhibits some rich and unexpected |
711 |
+ |
behaviors. It would clearly be a closer approximation to the reality |
712 |
+ |
if we allowed greater translational freedom to the dipoles and |
713 |
+ |
replaced the somewhat artificial lattice packing and the harmonic |
714 |
+ |
elastic tension with more realistic molecular modeling potentials. |
715 |
+ |
What we have done is to present a simple model which exhibits bulk |
716 |
+ |
non-thermal corrugation, and our explanation of this rippling |
717 |
+ |
phenomenon will help us design more accurate molecular models for |
718 |
+ |
corrugated membranes and experiments to test whether rippling is |
719 |
+ |
dipole-driven or not. |
720 |
+ |
|
721 |
+ |
\newpage |
722 |
|
\bibliography{mdripple} |
723 |
|
\end{document} |