| 3 |
|
|
| 4 |
|
\section{Introduction} |
| 5 |
|
\label{mdsec:Int} |
| 6 |
– |
Fully hydrated lipids will aggregate spontaneously to form bilayers |
| 7 |
– |
which exhibit a variety of phases depending on their temperatures and |
| 8 |
– |
compositions. Among these phases, a periodic rippled phase |
| 9 |
– |
($P_{\beta'}$) appears as an intermediate phase between the gel |
| 10 |
– |
($L_\beta$) and fluid ($L_{\alpha}$) phases for relatively pure |
| 11 |
– |
phosphatidylcholine (PC) bilayers. The ripple phase has attracted |
| 12 |
– |
substantial experimental interest over the past 30 years. Most |
| 13 |
– |
structural information of the ripple phase has been obtained by the |
| 14 |
– |
X-ray diffraction~\cite{Sun96,Katsaras00} and freeze-fracture electron |
| 15 |
– |
microscopy (FFEM).~\cite{Copeland80,Meyer96} Recently, Kaasgaard {\it |
| 16 |
– |
et al.} used atomic force microscopy (AFM) to observe ripple phase |
| 17 |
– |
morphology in bilayers supported on mica.~\cite{Kaasgaard03} The |
| 18 |
– |
experimental results provide strong support for a 2-dimensional |
| 19 |
– |
hexagonal packing lattice of the lipid molecules within the ripple |
| 20 |
– |
phase. This is a notable change from the observed lipid packing |
| 21 |
– |
within the gel phase,~\cite{Cevc87} although Tenchov {\it et al.} have |
| 22 |
– |
recently observed near-hexagonal packing in some phosphatidylcholine |
| 23 |
– |
(PC) gel phases.\cite{Tenchov2001} The X-ray diffraction work by |
| 24 |
– |
Katsaras {\it et al.} showed that a rich phase diagram exhibiting both |
| 25 |
– |
{\it asymmetric} and {\it symmetric} ripples is possible for lecithin |
| 26 |
– |
bilayers.\cite{Katsaras00} |
| 6 |
|
|
| 7 |
|
A number of theoretical models have been presented to explain the |
| 8 |
|
formation of the ripple phase. Marder {\it et al.} used a |
| 12 |
|
concave portions of the membrane correspond to more solid-like |
| 13 |
|
regions. Carlson and Sethna used a packing-competition model (in |
| 14 |
|
which head groups and chains have competing packing energetics) to |
| 15 |
< |
predict the formation of a ripple-like phase. Their model predicted |
| 16 |
< |
that the high-curvature portions have lower-chain packing and |
| 17 |
< |
correspond to more fluid-like regions. Goldstein and Leibler used a |
| 18 |
< |
mean-field approach with a planar model for {\em inter-lamellar} |
| 19 |
< |
interactions to predict rippling in multilamellar |
| 15 |
> |
predict the formation of a ripple-like phase~\cite{Carlson87}. Their |
| 16 |
> |
model predicted that the high-curvature portions have lower-chain |
| 17 |
> |
packing and correspond to more fluid-like regions. Goldstein and |
| 18 |
> |
Leibler used a mean-field approach with a planar model for {\em |
| 19 |
> |
inter-lamellar} interactions to predict rippling in multilamellar |
| 20 |
|
phases.~\cite{Goldstein88} McCullough and Scott proposed that the {\em |
| 21 |
|
anisotropy of the nearest-neighbor interactions} coupled to |
| 22 |
|
hydrophobic constraining forces which restrict height differences |
| 39 |
|
described the formation of symmetric ripple-like structures using a |
| 40 |
|
coarse grained solvent-head-tail bead model.\cite{Kranenburg2005} |
| 41 |
|
Their lipids consisted of a short chain of head beads tied to the two |
| 42 |
< |
longer ``chains''. |
| 42 |
> |
longer ``chains''. |
| 43 |
|
|
| 44 |
|
In contrast, few large-scale molecular modeling studies have been |
| 45 |
|
done due to the large size of the resulting structures and the time |
| 72 |
|
driving force for ripple formation, questions about the ordering of |
| 73 |
|
the head groups in ripple phase have not been settled. |
| 74 |
|
|
| 75 |
< |
In a recent paper, we presented a simple ``web of dipoles'' spin |
| 75 |
> |
In Ch.~\ref{chap:mc}, we presented a simple ``web of dipoles'' spin |
| 76 |
|
lattice model which provides some physical insight into relationship |
| 77 |
|
between dipolar ordering and membrane buckling.\cite{sun:031602} We |
| 78 |
|
found that dipolar elastic membranes can spontaneously buckle, forming |
| 84 |
|
work on the spontaneous formation of dipolar peptide chains into |
| 85 |
|
curved nano-structures.\cite{Tsonchev04,Tsonchev04II} |
| 86 |
|
|
| 87 |
< |
In this paper, we construct a somewhat more realistic molecular-scale |
| 87 |
> |
In this chapter, we construct a somewhat more realistic molecular-scale |
| 88 |
|
lipid model than our previous ``web of dipoles'' and use molecular |
| 89 |
|
dynamics simulations to elucidate the role of the head group dipoles |
| 90 |
|
in the formation and morphology of the ripple phase. We describe our |
| 101 |
|
\begin{figure} |
| 102 |
|
\centering |
| 103 |
|
\includegraphics[width=\linewidth]{./figures/mdLipidModels.pdf} |
| 104 |
< |
\caption{Three different representations of DPPC lipid molecules, |
| 104 |
> |
\caption[Three different representations of DPPC lipid |
| 105 |
> |
molecules]{Three different representations of DPPC lipid molecules, |
| 106 |
|
including the chemical structure, an atomistic model, and the |
| 107 |
|
head-body ellipsoidal coarse-grained model used in this |
| 108 |
|
work.\label{mdfig:lipidModels}} |
| 141 |
|
Pechukas.\cite{Berne72} The potential is constructed in the familiar |
| 142 |
|
form of the Lennard-Jones function using orientation-dependent |
| 143 |
|
$\sigma$ and $\epsilon$ parameters, |
| 144 |
< |
\begin{equation*} |
| 144 |
> |
\begin{multline} |
| 145 |
|
V_{ij}({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, {\mathbf{\hat |
| 146 |
|
r}_{ij}}) = 4\epsilon ({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, |
| 147 |
< |
{\mathbf{\hat r}_{ij}})\left[\left(\frac{\sigma_0}{r_{ij}-\sigma({\mathbf{\hat u}_i}, |
| 147 |
> |
{\mathbf{\hat r}_{ij}})\left[ \left(\frac{\sigma_0}{r_{ij}-\sigma({\mathbf{\hat u}_i}, |
| 148 |
|
{\mathbf{\hat u}_j}, {\mathbf{\hat r}_{ij}})+\sigma_0}\right)^{12} |
| 149 |
< |
-\left(\frac{\sigma_0}{r_{ij}-\sigma({\mathbf{\hat u}_i}, {\mathbf{\hat u}_j}, |
| 150 |
< |
{\mathbf{\hat r}_{ij}})+\sigma_0}\right)^6\right] |
| 149 |
> |
\right. \\ |
| 150 |
> |
\left. - \left(\frac{\sigma_0}{r_{ij}-\sigma({\mathbf{\hat u}_i}, |
| 151 |
> |
{\mathbf{\hat u}_j}, {\mathbf{\hat |
| 152 |
> |
r}_{ij}})+\sigma_0}\right)^6\right] |
| 153 |
|
\label{mdeq:gb} |
| 154 |
< |
\end{equation*} |
| 154 |
> |
\end{multline} |
| 155 |
|
|
| 156 |
|
The range $(\sigma({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf |
| 157 |
|
\hat{r}}_{ij}))$, and strength $(\epsilon({\bf \hat{u}}_{i},{\bf |
| 172 |
|
where $l$ and $d$ describe the length and width of each uniaxial |
| 173 |
|
ellipsoid. These shape anisotropy parameters can then be used to |
| 174 |
|
calculate the range function, |
| 175 |
< |
\begin{equation*} |
| 176 |
< |
\sigma({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf \hat{r}}_{ij}) = \sigma_{0} |
| 177 |
< |
\left[ 1- \left\{ \frac{ \chi \alpha^2 ({\bf \hat{u}}_i \cdot {\bf |
| 175 |
> |
\begin{multline} |
| 176 |
> |
\sigma({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf \hat{r}}_{ij}) = \\ |
| 177 |
> |
\sigma_0 \left[ 1 - \left\{ \frac{ \chi \alpha^2 ({\bf \hat{u}}_i \cdot {\bf |
| 178 |
|
\hat{r}}_{ij} ) + \chi \alpha^{-2} ({\bf \hat{u}}_j \cdot {\bf |
| 179 |
|
\hat{r}}_{ij} ) - 2 \chi^2 ({\bf \hat{u}}_i \cdot {\bf |
| 180 |
|
\hat{r}}_{ij} )({\bf \hat{u}}_j \cdot {\bf |
| 181 |
|
\hat{r}}_{ij} ) ({\bf \hat{u}}_i \cdot {\bf \hat{u}}_j)}{1 - \chi^2 |
| 182 |
|
\left({\bf \hat{u}}_i \cdot {\bf \hat{u}}_j\right)^2} \right\} |
| 183 |
|
\right]^{-1/2} |
| 184 |
< |
\end{equation*} |
| 184 |
> |
\end{multline} |
| 185 |
|
|
| 186 |
|
Gay-Berne ellipsoids also have an energy scaling parameter, |
| 187 |
|
$\epsilon^s$, which describes the well depth for two identical |
| 199 |
|
\alpha'^2 & = & \left[1 + (\epsilon^r)^{1/\mu}\right]^{-1} |
| 200 |
|
\end{eqnarray*} |
| 201 |
|
The form of the strength function is somewhat complicated, |
| 202 |
< |
\begin {eqnarray*} |
| 202 |
> |
\begin{eqnarray*} |
| 203 |
|
\epsilon({\bf \hat{u}}_{i}, {\bf \hat{u}}_{j},{\bf \hat{r}}_{ij}) & = & |
| 204 |
|
\epsilon_{0} \epsilon_{1}^{\nu}({\bf \hat{u}}_{i}.{\bf \hat{u}}_{j}) |
| 205 |
|
\epsilon_{2}^{\mu}({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf |
| 206 |
|
\hat{r}}_{ij}) \\ \\ |
| 207 |
|
\epsilon_{1}({\bf \hat{u}}_{i},{\bf \hat{u}}_{j}) & = & |
| 208 |
|
\left[1-\chi^{2}({\bf \hat{u}}_{i}.{\bf |
| 209 |
< |
\hat{u}}_{j})^{2}\right]^{-1/2} \\ \\ |
| 210 |
< |
\epsilon_{2}({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf \hat{r}}_{ij}) & |
| 211 |
< |
= & |
| 212 |
< |
1 - \left\{ \frac{ \chi' \alpha'^2 ({\bf \hat{u}}_i \cdot {\bf |
| 209 |
> |
\hat{u}}_{j})^{2}\right]^{-1/2} |
| 210 |
> |
\end{eqnarray*} |
| 211 |
> |
\begin{multline*} |
| 212 |
> |
\epsilon_{2}({\bf \hat{u}}_{i},{\bf \hat{u}}_{j},{\bf \hat{r}}_{ij}) |
| 213 |
> |
= \\ |
| 214 |
> |
1 - \left\{ \frac{ \chi' \alpha'^2 ({\bf \hat{u}}_i \cdot {\bf |
| 215 |
|
\hat{r}}_{ij} ) + \chi' \alpha'^{-2} ({\bf \hat{u}}_j \cdot {\bf |
| 216 |
|
\hat{r}}_{ij} ) - 2 \chi'^2 ({\bf \hat{u}}_i \cdot {\bf |
| 217 |
|
\hat{r}}_{ij} )({\bf \hat{u}}_j \cdot {\bf |
| 218 |
|
\hat{r}}_{ij} ) ({\bf \hat{u}}_i \cdot {\bf \hat{u}}_j)}{1 - \chi'^2 |
| 219 |
|
\left({\bf \hat{u}}_i \cdot {\bf \hat{u}}_j\right)^2} \right\}, |
| 220 |
< |
\end {eqnarray*} |
| 220 |
> |
\end{multline*} |
| 221 |
|
although many of the quantities and derivatives are identical with |
| 222 |
|
those obtained for the range parameter. Ref. \citen{Luckhurst90} |
| 223 |
|
has a particularly good explanation of the choice of the Gay-Berne |
| 244 |
|
\begin{figure} |
| 245 |
|
\centering |
| 246 |
|
\includegraphics[width=\linewidth]{./figures/md2LipidModel.pdf} |
| 247 |
< |
\caption{The parameters defining the behavior of the lipid |
| 248 |
< |
models. $\sigma_h / d$ is the ratio of the head group to body diameter. |
| 249 |
< |
Molecular bodies had a fixed aspect ratio of 3.0. The solvent model |
| 250 |
< |
was a simplified 4-water bead ($\sigma_w \approx d$) that has been |
| 251 |
< |
used in other coarse-grained simulations. The dipolar strength |
| 252 |
< |
(and the temperature and pressure) were the only other parameters that |
| 253 |
< |
were varied systematically.\label{mdfig:lipidModel}} |
| 247 |
> |
\caption[The parameters defining the behavior of the lipid |
| 248 |
> |
models]{The parameters defining the behavior of the lipid |
| 249 |
> |
models. $\sigma_h / d$ is the ratio of the head group to body |
| 250 |
> |
diameter. Molecular bodies had a fixed aspect ratio of 3.0. The |
| 251 |
> |
solvent model was a simplified 4-water bead ($\sigma_w \approx d$) |
| 252 |
> |
that has been used in other coarse-grained simulations. The dipolar |
| 253 |
> |
strength (and the temperature and pressure) were the only other |
| 254 |
> |
parameters that were varied systematically.\label{mdfig:lipidModel}} |
| 255 |
|
\end{figure} |
| 256 |
|
|
| 257 |
|
To take into account the permanent dipolar interactions of the |
| 323 |
|
\begin{table*} |
| 324 |
|
\begin{minipage}{\linewidth} |
| 325 |
|
\begin{center} |
| 326 |
< |
\caption{Potential parameters used for molecular-scale coarse-grained |
| 327 |
< |
lipid simulations} |
| 326 |
> |
\caption{POTENTIAL PARAMETERS USED FOR MOLECULAR SCALE COARSE-GRAINED |
| 327 |
> |
LIPID SIMULATIONS} |
| 328 |
|
\begin{tabular}{llccc} |
| 329 |
|
\hline |
| 330 |
|
& & Head & Chain & Solvent \\ |
| 345 |
|
\end{minipage} |
| 346 |
|
\end{table*} |
| 347 |
|
|
| 348 |
< |
\section{Experimental Methodology} |
| 349 |
< |
\label{mdsec:experiment} |
| 348 |
> |
\section{Simulation Methodology} |
| 349 |
> |
\label{mdsec:simulation} |
| 350 |
|
|
| 351 |
|
The parameters that were systematically varied in this study were the |
| 352 |
|
size of the head group ($\sigma_h$), the strength of the dipole moment |
| 441 |
|
\begin{figure} |
| 442 |
|
\centering |
| 443 |
|
\includegraphics[width=\linewidth]{./figures/mdPhaseCartoon.pdf} |
| 444 |
< |
\caption{The role of the ratio between the head group size and the |
| 445 |
< |
width of the molecular bodies is to increase the local membrane |
| 446 |
< |
curvature. With strong attractive interactions between the head |
| 447 |
< |
groups, this local curvature can be maintained in bilayer structures |
| 448 |
< |
through surface corrugation. Shown above are three phases observed in |
| 449 |
< |
these simulations. With $\sigma_h = 1.20 d$, the bilayer maintains a |
| 450 |
< |
flat topology. For larger heads ($\sigma_h = 1.35 d$) the local |
| 451 |
< |
curvature resolves into a symmetrically rippled phase with little or |
| 452 |
< |
no interdigitation between the upper and lower leaves of the membrane. |
| 453 |
< |
The largest heads studied ($\sigma_h = 1.41 d$) resolve into an |
| 454 |
< |
asymmetric rippled phases with interdigitation between the two |
| 455 |
< |
leaves.\label{mdfig:phaseCartoon}} |
| 444 |
> |
\caption[ three phases observed in the simulations]{The role of the |
| 445 |
> |
ratio between the head group size and the width of the molecular |
| 446 |
> |
bodies is to increase the local membrane curvature. With strong |
| 447 |
> |
attractive interactions between the head groups, this local curvature |
| 448 |
> |
can be maintained in bilayer structures through surface corrugation. |
| 449 |
> |
Shown above are three phases observed in these simulations. With |
| 450 |
> |
$\sigma_h = 1.20 d$, the bilayer maintains a flat topology. For |
| 451 |
> |
larger heads ($\sigma_h = 1.35 d$) the local curvature resolves into a |
| 452 |
> |
symmetrically rippled phase with little or no interdigitation between |
| 453 |
> |
the upper and lower leaves of the membrane. The largest heads studied |
| 454 |
> |
($\sigma_h = 1.41 d$) resolve into an asymmetric rippled phases with |
| 455 |
> |
interdigitation between the two leaves.\label{mdfig:phaseCartoon}} |
| 456 |
|
\end{figure} |
| 457 |
|
|
| 458 |
|
Sample structures for the flat ($\sigma_h = 1.20 d$), symmetric |
| 461 |
|
|
| 462 |
|
It is reasonable to ask how well the parameters we used can produce |
| 463 |
|
bilayer properties that match experimentally known values for real |
| 464 |
< |
lipid bilayers. Using a value of $l = 13.8$ \AA for the ellipsoidal |
| 464 |
> |
lipid bilayers. Using a value of $l = 13.8$ \AA~for the ellipsoidal |
| 465 |
|
tails and the fixed ellipsoidal aspect ratio of 3, our values for the |
| 466 |
|
area per lipid ($A$) and inter-layer spacing ($D_{HH}$) depend |
| 467 |
|
entirely on the size of the head bead relative to the molecular body. |
| 478 |
|
for PE head groups. |
| 479 |
|
|
| 480 |
|
\begin{table*} |
| 496 |
– |
\begin{minipage}{\linewidth} |
| 481 |
|
\begin{center} |
| 482 |
< |
\caption{Phase, bilayer spacing, area per lipid, ripple wavelength |
| 483 |
< |
and amplitude observed as a function of the ratio between the head |
| 484 |
< |
beads and the diameters of the tails. Ripple wavelengths and |
| 501 |
< |
amplitudes are normalized to the diameter of the tail ellipsoids.} |
| 482 |
> |
\caption{PHASE, BILAYER SPACING, AREA PER LIPID, RIPPLE WAVELENGTH AND |
| 483 |
> |
AMPLITUDE OBSERVED AS A FUNCTION OF THE RATIO BETWEEN THE HEAD BEADS |
| 484 |
> |
AND THE DIAMETERS OF THE TAILS} |
| 485 |
|
\begin{tabular}{lccccc} |
| 486 |
|
\hline |
| 487 |
|
$\sigma_h / d$ & type of phase & bilayer spacing (\AA) & area per |
| 492 |
|
1.35 & symmetric ripple & 42.9 & 51.7 & 17.2 & 2.2 \\ |
| 493 |
|
1.41 & asymmetric ripple & 37.1 & 63.1 & 15.4 & 1.5 \\ |
| 494 |
|
\end{tabular} |
| 495 |
+ |
\begin{minipage}{\linewidth} |
| 496 |
+ |
%\centering |
| 497 |
+ |
\vspace{2mm} |
| 498 |
+ |
Ripple wavelengths and amplitudes are normalized to the diameter of |
| 499 |
+ |
the tail ellipsoids. |
| 500 |
|
\label{mdtab:property} |
| 513 |
– |
\end{center} |
| 501 |
|
\end{minipage} |
| 502 |
+ |
\end{center} |
| 503 |
|
\end{table*} |
| 504 |
|
|
| 505 |
|
The membrane structures and the reduced wavelength $\lambda / d$, |
| 515 |
|
\begin{figure} |
| 516 |
|
\centering |
| 517 |
|
\includegraphics[width=\linewidth]{./figures/mdTopDown.pdf} |
| 518 |
< |
\caption{Top views of the flat (upper), symmetric ripple (middle), |
| 519 |
< |
and asymmetric ripple (lower) phases. Note that the head-group |
| 520 |
< |
dipoles have formed head-to-tail chains in all three of these phases, |
| 521 |
< |
but in the two rippled phases, the dipolar chains are all aligned {\it |
| 522 |
< |
perpendicular} to the direction of the ripple. Note that the flat |
| 523 |
< |
membrane has multiple vortex defects in the dipolar ordering, and the |
| 524 |
< |
ordering on the lower leaf of the bilayer can be in an entirely |
| 525 |
< |
different direction from the upper leaf.\label{mdfig:topView}} |
| 518 |
> |
\caption[Top views of the flat, symmetric ripple, and asymmetric |
| 519 |
> |
ripple phases]{Top views of the flat (upper), symmetric ripple |
| 520 |
> |
(middle), and asymmetric ripple (lower) phases. Note that the |
| 521 |
> |
head-group dipoles have formed head-to-tail chains in all three of |
| 522 |
> |
these phases, but in the two rippled phases, the dipolar chains are |
| 523 |
> |
all aligned {\it perpendicular} to the direction of the ripple. Note |
| 524 |
> |
that the flat membrane has multiple vortex defects in the dipolar |
| 525 |
> |
ordering, and the ordering on the lower leaf of the bilayer can be in |
| 526 |
> |
an entirely different direction from the upper |
| 527 |
> |
leaf.\label{mdfig:topView}} |
| 528 |
|
\end{figure} |
| 529 |
|
|
| 530 |
< |
The principal method for observing orientational ordering in dipolar |
| 531 |
< |
or liquid crystalline systems is the $P_2$ order parameter (defined |
| 532 |
< |
as $1.5 \times \lambda_{max}$, where $\lambda_{max}$ is the largest |
| 543 |
< |
eigenvalue of the matrix, |
| 544 |
< |
\begin{equation} |
| 545 |
< |
{\mathsf{S}} = \frac{1}{N} \sum_i \left( |
| 546 |
< |
\begin{array}{ccc} |
| 547 |
< |
u^{x}_i u^{x}_i-\frac{1}{3} & u^{x}_i u^{y}_i & u^{x}_i u^{z}_i \\ |
| 548 |
< |
u^{y}_i u^{x}_i & u^{y}_i u^{y}_i -\frac{1}{3} & u^{y}_i u^{z}_i \\ |
| 549 |
< |
u^{z}_i u^{x}_i & u^{z}_i u^{y}_i & u^{z}_i u^{z}_i -\frac{1}{3} |
| 550 |
< |
\end{array} \right). |
| 551 |
< |
\label{mdeq:opmatrix} |
| 552 |
< |
\end{equation} |
| 553 |
< |
Here $u^{\alpha}_i$ is the $\alpha=x,y,z$ component of the unit vector |
| 554 |
< |
for molecule $i$. (Here, $\hat{\bf u}_i$ can refer either to the |
| 530 |
> |
The orientational ordering in the system is observed by $P_2$ order |
| 531 |
> |
parameter, which is calculated from Eq.~\ref{mceq:opmatrix} |
| 532 |
> |
in Ch.~\ref{chap:mc}. Here, $\hat{\bf u}_i$ can refer either to the |
| 533 |
|
principal axis of the molecular body or to the dipole on the head |
| 534 |
< |
group of the molecule.) $P_2$ will be $1.0$ for a perfectly-ordered |
| 535 |
< |
system and near $0$ for a randomized system. Note that this order |
| 536 |
< |
parameter is {\em not} equal to the polarization of the system. For |
| 537 |
< |
example, the polarization of a perfect anti-ferroelectric arrangement |
| 560 |
< |
of point dipoles is $0$, but $P_2$ for the same system is $1$. The |
| 561 |
< |
eigenvector of $\mathsf{S}$ corresponding to the largest eigenvalue is |
| 562 |
< |
familiar as the director axis, which can be used to determine a |
| 563 |
< |
privileged axis for an orientationally-ordered system. Since the |
| 564 |
< |
molecular bodies are perpendicular to the head group dipoles, it is |
| 565 |
< |
possible for the director axes for the molecular bodies and the head |
| 566 |
< |
groups to be completely decoupled from each other. |
| 534 |
> |
group of the molecule. Since the molecular bodies are perpendicular to |
| 535 |
> |
the head group dipoles, it is possible for the director axes for the |
| 536 |
> |
molecular bodies and the head groups to be completely decoupled from |
| 537 |
> |
each other. |
| 538 |
|
|
| 539 |
|
Figure \ref{mdfig:topView} shows snapshots of bird's-eye views of the |
| 540 |
|
flat ($\sigma_h = 1.20 d$) and rippled ($\sigma_h = 1.35, 1.41 d$) |
| 589 |
|
\begin{figure} |
| 590 |
|
\centering |
| 591 |
|
\includegraphics[width=\linewidth]{./figures/mdRP2.pdf} |
| 592 |
< |
\caption{The $P_2$ order parameters for head groups (circles) and |
| 593 |
< |
molecular bodies (squares) as a function of the ratio of head group |
| 594 |
< |
size ($\sigma_h$) to the width of the molecular bodies ($d$). \label{mdfig:rP2}} |
| 592 |
> |
\caption[The $P_2$ order parameters as a function of the ratio of head group |
| 593 |
> |
size to the width of the molecular bodies]{The $P_2$ order parameters |
| 594 |
> |
for head groups (circles) and molecular bodies (squares) as a function |
| 595 |
> |
of the ratio of head group size ($\sigma_h$) to the width of the |
| 596 |
> |
molecular bodies ($d$). \label{mdfig:rP2}} |
| 597 |
|
\end{figure} |
| 598 |
|
|
| 599 |
|
In addition to varying the size of the head groups, we studied the |
| 642 |
|
\begin{figure} |
| 643 |
|
\centering |
| 644 |
|
\includegraphics[width=\linewidth]{./figures/mdSP2.pdf} |
| 645 |
< |
\caption{The $P_2$ order parameters for head group dipoles (a) and |
| 646 |
< |
molecular bodies (b) as a function of the strength of the dipoles. |
| 645 |
> |
\caption[The $P_2$ order parameters as a function of the strength of |
| 646 |
> |
the dipoles.]{The $P_2$ order parameters for head group dipoles (a) |
| 647 |
> |
and molecular bodies (b) as a function of the strength of the dipoles. |
| 648 |
|
These order parameters are shown for four values of the head group / |
| 649 |
|
molecular width ratio ($\sigma_h / d$). \label{mdfig:sP2}} |
| 650 |
|
\end{figure} |
| 675 |
|
\begin{figure} |
| 676 |
|
\centering |
| 677 |
|
\includegraphics[width=\linewidth]{./figures/mdTP2.pdf} |
| 678 |
< |
\caption{The $P_2$ order parameters for head group dipoles (a) and |
| 679 |
< |
molecular bodies (b) as a function of temperature. |
| 680 |
< |
These order parameters are shown for four values of the head group / |
| 681 |
< |
molecular width ratio ($\sigma_h / d$).\label{mdfig:tP2}} |
| 678 |
> |
\caption[The $P_2$ order parameters as a function of temperature]{The |
| 679 |
> |
$P_2$ order parameters for head group dipoles (a) and molecular bodies |
| 680 |
> |
(b) as a function of temperature. These order parameters are shown |
| 681 |
> |
for four values of the head group / molecular width ratio ($\sigma_h / |
| 682 |
> |
d$).\label{mdfig:tP2}} |
| 683 |
|
\end{figure} |
| 684 |
|
|
| 685 |
|
Fig. \ref{mdfig:phaseDiagram} shows a phase diagram for the model as a |
| 698 |
|
\begin{figure} |
| 699 |
|
\centering |
| 700 |
|
\includegraphics[width=\linewidth]{./figures/mdPhaseDiagram.pdf} |
| 701 |
< |
\caption{Phase diagram for the simple molecular model as a function |
| 702 |
< |
of the head group / molecular width ratio ($\sigma_h / d$) and the |
| 703 |
< |
strength of the head group dipole moment |
| 704 |
< |
($\mu$).\label{mdfig:phaseDiagram}} |
| 701 |
> |
\caption[Phase diagram for the simple molecular model]{Phase diagram |
| 702 |
> |
for the simple molecular model as a function of the head group / |
| 703 |
> |
molecular width ratio ($\sigma_h / d$) and the strength of the head |
| 704 |
> |
group dipole moment ($\mu$).\label{mdfig:phaseDiagram}} |
| 705 |
|
\end{figure} |
| 706 |
|
|
| 707 |
|
We have computed translational diffusion constants for lipid molecules |
| 708 |
|
from the mean-square displacement, |
| 709 |
|
\begin{equation} |
| 710 |
< |
D = \lim_{t \rightarrow \infty} \frac{1}{6 t} \langle {|\left({\bf r}_{i}(t) - {\bf r}_{i}(0) \right)|}^2 \rangle, |
| 710 |
> |
D = \lim_{t \rightarrow \infty} \frac{1}{6 t} \langle {|\left({\bf |
| 711 |
> |
r}_{i}(t) - {\bf r}_{i}(0) \right)|}^2 \rangle, |
| 712 |
> |
\label{mdeq:msdisplacement} |
| 713 |
|
\end{equation} |
| 714 |
|
of the lipid bodies. Translational diffusion constants for the |
| 715 |
|
different head-to-tail size ratios (all at 300 K) are shown in table |
| 750 |
|
times that are too fast when compared with experimental measurements. |
| 751 |
|
|
| 752 |
|
\begin{table*} |
| 776 |
– |
\begin{minipage}{\linewidth} |
| 753 |
|
\begin{center} |
| 754 |
< |
\caption{Fit values for the rotational correlation times for the head |
| 755 |
< |
groups ($\tau^h$) and molecular bodies ($\tau^b$) as well as the |
| 756 |
< |
translational diffusion constants for the molecule as a function of |
| 757 |
< |
the head-to-body width ratio. All correlation functions and transport |
| 782 |
< |
coefficients were computed from microcanonical simulations with an |
| 783 |
< |
average temperture of 300 K. In all of the phases, the head group |
| 784 |
< |
correlation functions decay with an fast librational contribution ($12 |
| 785 |
< |
\pm 1$ ps). There are additional moderate ($\tau^h_{\rm mid}$) and |
| 786 |
< |
slow $\tau^h_{\rm slow}$ contributions to orientational decay that |
| 787 |
< |
depend strongly on the phase exhibited by the lipids. The symmetric |
| 788 |
< |
ripple phase ($\sigma_h / d = 1.35$) appears to exhibit the slowest |
| 789 |
< |
molecular reorientation.} |
| 754 |
> |
\caption{FIT VALUES FOR THE ROTATIONAL CORRELATION TIMES FOR THE HEAD |
| 755 |
> |
GROUPS ($\tau^h$) AND MOLECULAR BODIES ($\tau^b$) AS WELL AS THE |
| 756 |
> |
TRANSLATIONAL DIFFUSION CONSTANTS FOR THE MOL\-E\-CULE AS A FUNCTION |
| 757 |
> |
OF THE HEAD-TO-BODY WIDTH RATIO} |
| 758 |
|
\begin{tabular}{lcccc} |
| 759 |
|
\hline |
| 760 |
|
$\sigma_h / d$ & $\tau^h_{\rm mid} (ns)$ & $\tau^h_{\rm |
| 765 |
|
1.35 & $3.2$ & $4.0$ & $0.9$ & $3.42(1)$ \\ |
| 766 |
|
1.41 & $0.3$ & $23.8$ & $6.9$ & $7.16(1)$ \\ |
| 767 |
|
\end{tabular} |
| 768 |
+ |
\begin{minipage}{\linewidth} |
| 769 |
+ |
%\centering |
| 770 |
+ |
\vspace{2mm} |
| 771 |
+ |
All correlation functions and transport coefficients were computed |
| 772 |
+ |
from microcanonical simulations with an average temperture of 300 K. |
| 773 |
+ |
In all of the phases, the head group correlation functions decay with |
| 774 |
+ |
an fast librational contribution ($12 \pm 1$ ps). There are |
| 775 |
+ |
additional moderate ($\tau^h_{\rm mid}$) and slow $\tau^h_{\rm slow}$ |
| 776 |
+ |
contributions to orientational decay that depend strongly on the phase |
| 777 |
+ |
exhibited by the lipids. The symmetric ripple phase ($\sigma_h / d = |
| 778 |
+ |
1.35$) appears to exhibit the slowest molecular reorientation. |
| 779 |
|
\label{mdtab:relaxation} |
| 801 |
– |
\end{center} |
| 780 |
|
\end{minipage} |
| 781 |
+ |
\end{center} |
| 782 |
|
\end{table*} |
| 783 |
|
|
| 784 |
|
\section{Discussion} |
| 852 |
|
orientations of the membrane dipoles may be available from |
| 853 |
|
fluorescence detected linear dichroism (LD). Benninger {\it et al.} |
| 854 |
|
have recently used axially-specific chromophores |
| 855 |
< |
2-(4,4-difluoro-5,7-dimethyl-4-bora-3a,4a-diaza-s-indacene-3-pentanoyl)-1-hexadecanoyl-sn-glycero-3-phospocholine |
| 856 |
< |
($\beta$-BODIPY FL C5-HPC or BODIPY-PC) and 3,3' |
| 855 |
> |
2-(4,4-difluoro-5,7-dimethyl-4-bora-3a,4a-diaza-s-indacene-3-pentanoyl)-1-hexadecanoyl-sn-glycero-3-\\ |
| 856 |
> |
phospocholine ($\beta$-BODIPY FL C5-HPC or BODIPY-PC) and 3,3' |
| 857 |
|
dioctadecyloxacarbocyanine perchlorate (DiO) in their |
| 858 |
|
fluorescence-detected linear dichroism (LD) studies of plasma |
| 859 |
|
membranes of living cells.\cite{Benninger:2005qy} The DiO dye aligns |
