Tianjin Key Laboratory for Modern Drug Delivery & High-Efficiency, School of Pharmaceutical Science and Technology, Tianjin University, Nankai District, Tianjin, People's Republic of China.
J Mol Model. 2011 Jun;17(6):1259-65. doi: 10.1007/s00894-010-0822-5. Epub 2010 Aug 26.
Retinoid X receptors (RXRα, β and γ) are recently known to be cancer chemotherapies targets. The ligand binding domains of RXRs have been crystallized, but the information of RXRγ ligand binding site is not yet available due to the lack of liganded complex. A thorough understanding of the ligand binding sites is essential to study RXRs and may result in cancer therapeutic breakthrough. Thus we aimed to study the RXRγ ligand binding site and find out the differences between the three subtypes. Alignment and molecular simulation were carried out for identifying the RXRγ ligand binding site, characterizing the RXRγ ligand binding mode and comparing the three RXRs. The result has indicated that the RXRγ ligand binding site is defined by helices H5, H10, β-sheet s1 and the end loop. Besides hydrophobic interactions, the ligand 9-cis retinoic acid interacts with RXRγ through a hydrogen bond with Ala106, a salt bridge with Arg95 and the π-π interactions with Phe217 and Phe218. The binding modes exhibit some similarities among RXRs, such as the interactions with Arg95 and Ala106. Nonetheless, owing to the absence of Ile47, Cys48, Ala50, Ala51 and residues 225∼237 in the active site, the binding pocket in RXRγ is two times larger than those of RXRα and RXRβ. Meanwhile, spatial effects of Trp84, Arg95, Ala106, Phe217 and Phe218 help to create a differently shaped binding pocket as compared to those of RXRα and RXRβ. Consequently, the ligand in RXRγ undergoes a "standing" posing which is distinct from the other two RXRs.
视黄酸 X 受体(RXRα、β 和 γ)最近被认为是癌症化疗的靶点。RXRs 的配体结合域已经结晶,但由于缺乏配体复合物,RXRγ 的配体结合位点的信息尚不可用。深入了解配体结合位点对于研究 RXRs 至关重要,并且可能会带来癌症治疗的突破。因此,我们旨在研究 RXRγ 的配体结合位点,并找出这三种亚型之间的差异。通过比对和分子模拟,确定了 RXRγ 的配体结合位点,描绘了 RXRγ 的配体结合模式,并比较了三种 RXRs。结果表明,RXRγ 的配体结合位点由 H5、H10、β-折叠 s1 和末端环定义。除了疏水相互作用外,配体 9-顺式视黄酸还通过与 Ala106 的氢键、与 Arg95 的盐桥以及与 Phe217 和 Phe218 的π-π相互作用与 RXRγ 相互作用。结合模式在 RXRs 之间表现出一些相似性,例如与 Arg95 和 Ala106 的相互作用。然而,由于活性位点中缺乏 Ile47、Cys48、Ala50、Ala51 和 225∼237 位的残基,RXRγ 的结合口袋比 RXRα 和 RXRβ 大两倍。同时,Trp84、Arg95、Ala106、Phe217 和 Phe218 的空间效应有助于创造出与 RXRα 和 RXRβ 不同形状的结合口袋。因此,RXRγ 中的配体呈现出一种“站立”的构象,与其他两种 RXR 不同。
