图 1  利用传统的位移和回旋半径PDF进行轨迹分析　(a) 轨迹的位移频数分布情况, 包括两类原始轨迹$ T(\sigma = 1) $, $ T(\sigma = 1. 25) $和二者混合之后的轨迹$ {T}_{\rm{mixed}} $; (b) 三类轨迹的回旋半径频数分布情况

Fig. 1.  Conventional PDF analysis of the displacement and $ {R}_{\rm{g}} $ of trajectories: (a) Displacement PDF of the trajectories before mixing ($ T(\sigma = 1) $, $ T(\sigma = 1. 25) $) and after mixing ($ {T}_{\rm{mixed}} $); (b) $ {R}_{\rm{g}} $ PDF of the three conditions.

图 2  利用D_std频数分布进行轨迹分析举例　(a)$ {T}_{\rm{mixed}}(\sigma = 1, 1. 25) $; (b)$ {T}_{\rm{mixed}}\left(\sigma = 1, 1. 5\right); $ (c)$ {T}_{\rm{mixed}}\left(\sigma = 1, 2\right); $ (d) 三种$ {T}_{\rm{mixed}} $经过D_std轨迹分离法处理之后所得轨迹数量的准确率

Fig. 2.  Typical examples showing trajectory analysis based on the PDF of D_std: (a)$ {T}_{\rm{mixed}}\left(\sigma = 1, 1. 25\right); $ (b)$ {T}_{\rm{mixed}}\left(\sigma = 1, 1. 5\right); $ (c)$ {T}_{\rm{mixed}}\left(\sigma = 1, 2\right); $ (d) accuracy of the seperation shown in Fig. (a) (c).

图 3  DOPC支撑脂双层膜内磷脂分子运动轨迹的D_std的频数分布分析　(a), (b) 典型的单个磷脂分子时间序列荧光成像照片(拍摄速率30 frames/s)及运动轨迹(总时长4.38 s). (c)—(e) 原始以及加入荧光淬灭剂之后的脂膜: (c)示意图; (d)分子轨迹D_std频数分布情况; (e) $ {T}_{\rm{slow}} $与 $ {T}_{\rm{fast}} $比例柱状图. 图(c)中红色为荧光脂分子, 蓝色为无荧光脂分子

Fig. 3.  PDF of D_std of the lipid trajectories in a DOPC SLB before or after fluorescence quenching: (a), (b) Representative lipid molecule in a pristine membrane, its time-serial images (at 30 frames/s) and trajectory (with a time duration of 4.38 s); (c)−(e) schematic diagram, PDF of D_std, and percentage histogram of the $ {T}_{\rm{slow}} $ and $ {T}_{\rm{fast}} $, of the membrane before and after outer-leaflet fluorescence quenching.

图 A2  原始脂膜内脂分子运动行为的回旋半径PDF分析　(a) 不同步长下的 ${R_{\rm{g}}}$频数分布以及相应的阈值; (b) 分别以${R_{\rm{g}}}$和${D_{\rm{std}}}$为标准分离轨迹得到的${T_{\rm{slow}}}$占比柱状图; (c) 纯DOPC脂膜中磷脂分子运动轨迹的回旋半径以及位移标准差之间的关系, 其中黑色线为拟合曲线, 二者呈现正相关

Fig. A2.  PDF analysis of ${R_{\rm{g}}}$ for the lipids in a pristine membrane: (a) PDF of ${R_{\rm{g}}}$ acquried with different step values (Step = 0.1, 0.2 or 0.3). Dashed lines show determination of the threshold value separating the trajectories. (b) Percentage of ${T_{\rm{slow}}}$ obtained by ${R_{\rm{g}}}$ or ${D_{\rm{std}}}$ analysis. (c) Relationship between ${R_{\rm{g}}}$ and ${D_{\rm{std}}}$ for a pure DOPC bilayer.

图 A3  不同步长的D_std的频数分布以及相应的高斯拟合　(a) 步长为0.05; (b) 步长为0.02; (c) 步长为0.04

Fig. A3.  PDF of D_std by different step and corresponding Gaussian fittings: (a) step = 0.05; (b) step = 0.02; (c) step = 0.04.

图 A4  不同浓度的蜂毒肽作用下的GUV泄露实验　(a)—(c) 分别在0.5, 5.0以及8 μg/mL的蜂毒肽的作用下的GUV泄露情况, 其中绿色通道为GUV中包裹的钙黄绿素, 红色通道代表GUV所在的轮廓; (d) 0—10 μg/mL各浓度的蜂毒肽对GUV的扰动情况; (e)浓度3 μg/mL蜂毒肽的作用下, 典型的GUV荧光泄露曲线; (f) 低浓度蜂毒肽吸附在脂膜以及高浓度蜂毒肽形成跨膜孔道的示意图

Fig. A4.  GUV leakage experiment incubated with different concentration of melittin: (a)–(c) Confocal images of GUV leakage incubated with 0.5, 5.0 and 8 μg/mL of melittin; (d) influence on GUV by different concentration of melittin; (e) typical leakage curve of GUV incubated with 3 μg/mL; (f) sketch of absorption or poration of melittin interacted with membrane.

图 4  蜂毒肽作用下的脂分子运动行为分析　(a), (b) 蜂毒肽影响下磷脂分子运动轨迹的D_std频数分布, 多肽浓度为 (a) 0.5 µg/mL, (b) 5.0 µg/mL; (c), (d) 三种实验体系内$ {T}_{\rm{fast}} $与$ {T}_{\rm{slow}} $的系综平均均方位移; (e) 三个体系中多肽与脂膜作用示意图

Fig. 4.  D_std PDF analysis of the melittin-exposed lipid membrane: (a), (b) PDF of D_std of lipids incubated with melittin at (a) 0.5 µg/mL and (b) 5.0 µg/mL; (c), (d) EA-MSD of $ {T}_{\rm{fast}} $ and $ {T}_{\rm{slow}} $ in the three systems; (e) cartoons showing melittin-membrane interactions in the three systems.

图 A5  分子动力学模拟中蜂毒肽影响下脂分子的扩散情况　(a) 代表性俯视截图, 显示蜂毒肽在脂膜表面的吸附; (b)脂分子的扩散图谱^[10]

Fig. A5.  Diffusion of lipids upon melittin exposure in molecular dynamics simulations: (a) Representative snapshot of melittin binding on a membrane (top view); (b) diffusion map of individual lipids^[10].

图 A1  数值模拟所得的σ = 1的四条代表轨迹

Fig. A1.  Four typical trajectories with σ = 1 obtained from numeric simulations.