Tantillo C, Ding J, Jacobo-Molina A, Nanni R G, Boyer P L, Hughes S H, Pauwels R, Andries K, Janssen P A, Arnold E
Center for Advanced Biotechnology and Medicine, (CABM), Rutgers University Chemistry Department, Piscataway, NJ 08854-5638.
J Mol Biol. 1994 Oct 28;243(3):369-87. doi: 10.1006/jmbi.1994.1665.
The locations of HIV-1 RT nucleoside and non-nucleoside inhibitor-binding sites and inhibitor-resistance mutations are analyzed in the context of the three-dimensional structure of the enzyme and implications for mechanisms of drug inhibition and resistance are discussed. In order to help identify residues that may play a role in inhibitor binding, solvent accessibilities of amino acids that comprise the inhibitor-binding sites in the structure of HIV-1 RT complexed with a dsDNA template-primer are analyzed. While some mutations that cause resistance to nucleoside analogs, such as AZT, ddI, and ddC, are located near enough to the dNTP-binding site to directly interfere with binding of nucleoside analogs, many are located away from the dNTP-binding site and more likely confer resistance by other mechanisms. Many of the latter mutations are located on the surface of the DNA-binding cleft and may lead to altered template-primer positioning or conformation, causing a distortion of the geometry of the polymerase active site and consequent discrimination between normal and altered dNTP substrates. Other nucleoside analog-resistance mutations located on the periphery of the dNTP-binding site may exert their effects via altered interactions with dNTP-binding site residues. The structure of the hydrophobic region in HIV-1 RT that binds non-nucleoside inhibitors, for example, nevirapine and TIBO, has been analyzed in the absence of bound ligand. The pocket that is present when non-nucleoside inhibitors are bound is not observed in the inhibitor-free structure of HIV-1 RT with dsDNA. In particular it is filled by Tyr181 and Tyr188, suggesting that the pocket is formed primarily by rotation of these large aromatic side-chains. Existing biochemical data, taken together with the three-dimensional structure of HIV-1 RT, makes it possible to propose potential mechanisms of inhibition by non-nucleoside inhibitors. One such mechanism is local distortion of HIV-1 RT structural elements thought to participate in catalysis: the beta 9-beta 10 hairpin (which contains polymerase active site residues) and the beta 12-beta 13 hairpin ("primer grip"). An alternative possibility is restricted mobility of the p66 thumb subdomain, which is supported by the observation that structural elements of the non-nucleoside inhibitor-binding pocket may act as a "hinge" for the thumb.(ABSTRACT TRUNCATED AT 400 WORDS)
在酶的三维结构背景下,分析了HIV-1逆转录酶核苷和非核苷抑制剂结合位点的位置以及抑制剂抗性突变,并讨论了其对药物抑制和抗性机制的影响。为了帮助确定可能在抑制剂结合中起作用的残基,分析了与双链DNA模板引物复合的HIV-1逆转录酶结构中构成抑制剂结合位点的氨基酸的溶剂可及性。虽然一些导致对核苷类似物(如齐多夫定、去羟肌苷和双脱氧胞苷)产生抗性的突变距离dNTP结合位点足够近,可直接干扰核苷类似物的结合,但许多突变位于远离dNTP结合位点的位置,更可能通过其他机制赋予抗性。后一类突变中的许多位于DNA结合裂隙的表面,可能导致模板引物定位或构象改变,引起聚合酶活性位点几何形状的扭曲,从而导致对正常和改变的dNTP底物的区分。位于dNTP结合位点外围的其他核苷类似物抗性突变可能通过与dNTP结合位点残基的相互作用改变而发挥作用。例如,在没有结合配体的情况下,分析了HIV-1逆转录酶中结合非核苷抑制剂(如奈韦拉平和替诺福韦)的疏水区域的结构。在与双链DNA结合的HIV-1逆转录酶的无抑制剂结构中未观察到结合非核苷抑制剂时存在的口袋。特别是它被Tyr181和Tyr188填充,这表明该口袋主要由这些大的芳香侧链的旋转形成。现有的生化数据与HIV-1逆转录酶的三维结构相结合,使得有可能提出非核苷抑制剂的潜在抑制机制。一种这样的机制是HIV-1逆转录酶结构元件的局部扭曲,这些元件被认为参与催化作用:β9-β10发夹(包含聚合酶活性位点残基)和β12-β13发夹(“引物夹”)。另一种可能性是p66拇指亚结构域的移动受限,这一观点得到了以下观察结果的支持:非核苷抑制剂结合口袋的结构元件可能作为拇指的“铰链”.(摘要截断于400字)
