Ertekin Asli, Nussinov Ruth, Haliloglu Turkan
Polymer Research Center and Chemical Engineering Department, Bogazici University, Bebek 34342, Istanbul, Turkey.
Protein Sci. 2006 Oct;15(10):2265-77. doi: 10.1110/ps.051815006.
Here, we propose a binding site prediction method based on the high frequency end of the spectrum in the native state of the protein structural dynamics. The spectrum is obtained using an elastic network model (GNM). High frequency vibrating (HFV) residues are determined from the fastest modes dynamics. HFV residue clusters and the associated surface patch residues are tested for their likelihood to locate at the binding interfaces using two different data sets, the Benchmark Set of mainly enzymes and antigen/antibodies and the Cluster Set of more diverse structures. The binding interface is identified to be within 7.5 A of the HFV residue clusters in the Benchmark Set and Cluster Set, for 77% and 70% of the structures, respectively. The success rate increases to 88% and 84%, respectively, by using the surface patches. The results suggest that concave binding interfaces, typically those of enzyme-binding sites, are enriched by the HFV residues. Thus, we expect that the association of HFV residues with the interfaces is mostly for enzymes. If, however, a binding region has invaginations and cavities, as in some of the antigen/antibodies and in cases in the Cluster data set, we expect it would be detected there too. This implies that binding sites possess several (inter-related) properties such as cavities, high packing density, conservation, and disposition for hotspots at binding surfaces. It further suggests that the high frequency vibrating residue-based approach is a potential tool for identification of regions likely to serve as protein-binding sites. The software is available at http://www.prc.boun.edu.tr/PRC/software.html.
在此,我们提出了一种基于蛋白质结构动力学天然状态下频谱高频端的结合位点预测方法。该频谱是使用弹性网络模型(GNM)获得的。高频振动(HFV)残基是根据最快模式动力学确定的。使用两个不同的数据集,即主要为酶和抗原/抗体的基准集以及结构更多样化的聚类集,测试HFV残基簇和相关的表面斑块残基位于结合界面的可能性。在基准集和聚类集中,分别有77%和70%的结构,其结合界面被确定在HFV残基簇的7.5埃范围内。通过使用表面斑块,成功率分别提高到88%和84%。结果表明,凹形结合界面,通常是酶结合位点的界面,富含HFV残基。因此,我们预计HFV残基与界面的关联主要是针对酶的。然而,如果一个结合区域有凹陷和空洞,如在一些抗原/抗体以及聚类数据集中的情况,我们预计在那里也能检测到。这意味着结合位点具有几个(相互关联的)特性,如空洞、高堆积密度、保守性以及在结合表面的热点分布。这进一步表明基于高频振动残基的方法是识别可能作为蛋白质结合位点区域的潜在工具。该软件可在http://www.prc.boun.edu.tr/PRC/software.html获取。