Guo Shan, Moore Timothy C, Iacovella Christopher R, Strickland L Anderson, McCabe Clare
Department of Chemical and Biomolecular Engineering, Vanderbilt University, Nashville, TN, 37235, USA.
Department of Chemical and Biomolecular Engineering, Vanderbilt University, Nashville, TN, 37235, USA ; Department of Chemistry, Vanderbilt University, Nashville, TN, 37235, USA.
J Chem Theory Comput. 2013 Nov 12;9(11):5116-5126. doi: 10.1021/ct400431e.
Ceramides are known to be a key component of the stratum corneum, the outermost protective layer of the skin that controls barrier function. In this work, molecular dynamics simulations are used to examine the behavior of ceramide bilayers, focusing on non-hydroxy sphingosine (NS) and non-hydroxy phytosphingosine (NP) ceramides. Here, we propose a modified version of the CHARMM force field for ceramide simulation, which is directly compared to the more commonly used GROMOS-based force field of Berger (Biophys. J. 1997, 72); while both force fields are shown to closely match experiment from a structural standpoint at the physiological temperature of skin, the modified CHARMM force field is better able to capture the thermotropic phase transitions observed in experiment. The role of ceramide chemistry and its impact on structural ordering is examined by comparing ceramide NS to NP, using the validated CHARMM-based force field. These simulations demonstrate that changing from ceramide NS to NP results in changes to the orientation of the OH groups in the lipid headgroups. The arrangement of OH groups perpendicular to the bilayer normal for ceramide NP, verse parallel for NS, results in the formation of a distinct hydrogen bonding network, that is ultimately responsible for shifting the gel-to-liquid phase transition to higher temperature, in direct agreement with experiment.
神经酰胺是已知的角质层的关键成分,角质层是皮肤最外层的保护层,控制着屏障功能。在这项工作中,分子动力学模拟用于研究神经酰胺双层的行为,重点是非羟基鞘氨醇(NS)和非羟基植物鞘氨醇(NP)神经酰胺。在这里,我们提出了一种用于神经酰胺模拟的CHARMM力场的改进版本,并将其直接与更常用的基于GROMOS的Berger力场(《生物物理杂志》,1997年,第72期)进行比较;虽然从结构角度来看,这两种力场在皮肤生理温度下都与实验结果紧密匹配,但改进后的CHARMM力场更能捕捉实验中观察到的热致相变。通过使用经过验证的基于CHARMM的力场,将神经酰胺NS与NP进行比较,研究了神经酰胺化学的作用及其对结构有序性的影响。这些模拟表明,从神经酰胺NS转变为NP会导致脂质头部基团中OH基团的取向发生变化。神经酰胺NP的OH基团垂直于双层法线排列,而NS则平行排列,这导致形成了一个独特的氢键网络,最终导致凝胶-液相转变温度升高,这与实验结果直接一致。