Bryan Michael A, Brauner Joseph W, Anderle Gloria, Flach Carol R, Brodsky Barbara, Mendelsohn Richard
Department of Biochemistry, University of Medicine and Dentistry of New Jersey, Robert Wood Johnson Medical School, Piscataway, New Jersey, USA.
J Am Chem Soc. 2007 Jun 27;129(25):7877-84. doi: 10.1021/ja071154i. Epub 2007 Jun 6.
X-ray crystallography of collagen model peptides has provided high-resolution structures of the basic triple-helical conformation and its water-mediated hydration network. Vibrational spectroscopy provides a useful bridge for transferring the structural information from X-ray diffraction to collagen in its native environment. The vibrational mode most useful for this purpose is the amide I mode (mostly peptide bond C=O stretch) near 1650 cm-1. The current study refines and extends the range of utility of a novel simulation method that accurately predicts the infrared (IR) amide I spectral contour from the three-dimensional structure of a protein or peptide. The approach is demonstrated through accurate simulation of the experimental amide I contour in solution for both a standard triple helix, (Pro-Pro-Gly)10, and a second peptide with a Gly --> Ala substitution in the middle of the chain that models the effect of a mutation in the native collagen sequence. Monitoring the major amide I peak as a function of temperature gives sharp thermal transitions for both peptides, similar to those obtained by circular dichroism spectroscopy, and the Fourier transform infrared (FTIR) spectra of the unfolded states were compared with polyproline II. The simulation studies were extended to model early stages of thermal denaturation of (Pro-Pro-Gly)10. Dihedral angle changes suggested by molecular dynamics simulations were made in a stepwise fashion to generate peptide unwinding from each end, which emulates the effect of increasing temperature. Simulated bands from these new structures were then compared to the experimental bands obtained as temperature was increased. The similarity between the simulated and experimental IR spectra lends credence to the simulation method and paves the way for a variety of applications.
胶原蛋白模型肽的X射线晶体学已提供了基本三螺旋构象及其水介导的水合网络的高分辨率结构。振动光谱学为将X射线衍射的结构信息传递到天然环境中的胶原蛋白提供了一个有用的桥梁。最适用于此目的的振动模式是1650 cm-1附近的酰胺I模式(主要是肽键C=O伸缩振动)。当前的研究改进并扩展了一种新型模拟方法的应用范围,该方法可根据蛋白质或肽的三维结构准确预测红外(IR)酰胺I光谱轮廓。通过对标准三螺旋(Pro-Pro-Gly)10和链中间具有Gly→Ala取代的第二种肽在溶液中的实验酰胺I轮廓进行精确模拟,证明了该方法,该肽模拟了天然胶原蛋白序列中突变的影响。监测主要酰胺I峰随温度的变化,两种肽都有明显的热转变,类似于通过圆二色光谱法获得的转变,并将未折叠状态的傅里叶变换红外(FTIR)光谱与聚脯氨酸II进行了比较。模拟研究扩展到对(Pro-Pro-Gly)10热变性的早期阶段进行建模。分子动力学模拟表明的二面角变化以逐步方式进行,以从两端产生肽解旋,这模拟了温度升高的影响。然后将这些新结构的模拟谱带与温度升高时获得的实验谱带进行比较。模拟红外光谱与实验红外光谱之间的相似性为模拟方法提供了可信度,并为各种应用铺平了道路。