利用 X 射线散射和 MD 模拟研究染料木黄酮和大豆黄酮生物类黄酮与脂膜的结构和弹性。
Structure and elasticity of lipid membranes with genistein and daidzein bioflavinoids using X-ray scattering and MD simulations.
机构信息
Physics Department, Carnegie Mellon University, Pittsburgh, Pennsylvania 15213, United States.
出版信息
J Phys Chem B. 2012 Apr 5;116(13):3918-27. doi: 10.1021/jp211904j. Epub 2012 Feb 29.
Abstract
This work reports the effects of the bioflavinoids genistein and daidzein on lipid bilayers as determined by volume measurements, X-ray scattering, and molecular dynamics simulations. The experimental and simulated total molecular volumes were found to be in outstanding agreement with each other before the addition of genistein and daidzein and also after their addition. Both bioflavinoids inserted into the hydrocarbon region of both DOPC and diphytanoylPC near the carbonyls of the lipids and both decreased the bilayer thicknesses. The long axes of both bioflavinoids were oriented nearly parallel to the plane of the bilayer with their carbonyl groups preferentially pointed toward the proximal surface. A difference is that daidzein had a solubility limit of ∼0.14 mol fraction in DOPC (∼0.12 mol fraction in diphytanoylPC), whereas genistein was soluble at least to 0.20 mol fraction in both lipid membranes. Measurements of bending modulus K(C) and simulation results for area compressibility modulus K(A) indicate that both bioflavinoids soften bilayers.
摘要
本工作通过体积测量、X 射线散射和分子动力学模拟研究了生物类黄酮染料木黄酮和大豆苷元对脂质双层的影响。在添加染料木黄酮和大豆苷元之前和之后,实验和模拟的总分子体积彼此之间都非常吻合。两种生物类黄酮都插入到 DOPC 和二植烷酰基磷脂酰胆碱双层的烃区域,靠近脂质的羰基,并且都降低了双层的厚度。两种生物类黄酮的长轴几乎与双层平面平行,其羰基基团优先指向近表面。区别在于,大豆苷元在 DOPC 中的溶解度极限约为 0.14 摩尔分数(在二植烷酰基磷脂酰胆碱中约为 0.12 摩尔分数),而染料木黄酮在两种脂质膜中至少可溶解至 0.20 摩尔分数。弯曲模量 K(C)的测量和面积压缩模量 K(A)的模拟结果表明,两种生物类黄酮都使双层变软。
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