Chieffo Logan R, Shattuck Jeffrey T, Pinnick Eric, Amsden Jason J, Hong M K, Wang Feng, Erramilli Shyamsunder, Ziegler Lawrence D
Department of Chemistry, and Photonics Center, Boston University, 590 Commonwealth Avenue, Boston, MA 02215, USA.
J Phys Chem B. 2008 Oct 9;112(40):12776-82. doi: 10.1021/jp8012283. Epub 2008 Sep 13.
Ultrafast infrared spectroscopy of N 2O is shown to be a sensitive probe of hydrophobic and aqueous sites in lipid bilayers. Distinct rates of VER of the nu 3 antisymmetric stretching mode of N 2O can be distinguished for N 2O solvated in the acyl tail, interfacial water, and bulk water regions of hydrated dioleoylphosphatidylcholine (DOPC) bilayers. The lifetime of the interfacial N 2O population is hydration-dependent. This effect is attributed to changes in the density of intermolecular states resonant with the nu 3 band ( approximately 2230 cm (-1)) resulting from oriented interfacial water molecules near the lipid phosphate. Thus, the N 2O VER rate becomes a novel and experimentally convenient tool for reporting on the structure and dynamics of interfacial water in lipids and, potentially, in other biological systems.
N₂O的超快红外光谱被证明是脂质双层中疏水和亲水位点的灵敏探针。对于溶解在水合二油酰磷脂酰胆碱(DOPC)双层的酰基尾部、界面水和本体水区域中的N₂O,可以区分出N₂O的ν₃反对称伸缩模式的不同VER速率。界面N₂O群体的寿命取决于水合作用。这种效应归因于脂质磷酸附近定向界面水分子导致的与ν₃带(约2230 cm⁻¹)共振的分子间态密度的变化。因此,N₂O的VER速率成为一种新颖且实验方便的工具,可用于报告脂质中界面水以及潜在地其他生物系统中界面水的结构和动力学。