Di Fenza Armida, Rocchia Walter, Tozzini Valentina
NEST, Scuola Normale Superiore and CNR-INFM, IIT UdR, Piazza dei Cavalieri 7, I-56126 Pisa, Italy.
Proteins. 2009 Sep;76(4):946-58. doi: 10.1002/prot.22399.
A new and very promising strategy for HIV drug discovery consists in blocking the multiple functional interactions between HIV-1 integrase (IN) and its cellular cofactors. At present, this line of action is hindered by the absence of three-dimensional structures of IN in complex with any of them. In this article, we developed a full-length three-dimensional structure of IN, including the highly flexible terminal residues 270-288, which are not experimentally solved. Additionally, we built models of IN complexed to the human acetyltransferases GCN5 and p300 based on available structural and mutagenesis data. Then, we studied the dynamical behavior of these models by means of the Coarse-Grained Molecular Dynamics (CGMD) and Essential Dynamics (ED) to locate and characterize the nature of the largest collective motions. We found correlated motions involving distant regions of IN. Moreover, we found that these are influenced by the binding with the acetyltransferases (HATs). Taken together these findings suggest a way to affect the acetyltransferase binding by an allosteric type of inhibition and provide an important new approach for the drug design against HIV disease.
一种全新且极具前景的HIV药物研发策略是阻断HIV-1整合酶(IN)与其细胞辅因子之间的多种功能相互作用。目前,由于缺乏IN与其中任何一种辅因子形成复合物的三维结构,这一行动路线受到了阻碍。在本文中,我们构建了IN的全长三维结构,包括高度灵活的270 - 288位末端残基,这些残基尚未通过实验解析。此外,我们基于现有的结构和诱变数据构建了IN与人类乙酰转移酶GCN5和p300形成复合物的模型。然后,我们通过粗粒度分子动力学(CGMD)和主成分动力学(ED)研究了这些模型的动力学行为,以定位并表征最大集体运动的性质。我们发现了涉及IN远距离区域的相关运动。此外,我们发现这些运动受到与乙酰转移酶(HATs)结合的影响。综合这些发现,提出了一种通过变构抑制来影响乙酰转移酶结合的方法,并为抗HIV疾病的药物设计提供了一种重要的新途径。
