Benach J, Atrian S, Gonzàlez-Duarte R, Ladenstein R
Karolinska Institutet, Novum, Center for Structural Biochemistry, Huddinge, S-14157, Sweden.
J Mol Biol. 1999 Jun 4;289(2):335-55. doi: 10.1006/jmbi.1999.2765.
Drosophila alcohol dehydrogenase (DADH) is an NAD+-dependent enzyme that catalyzes the oxidation of alcohols to aldehydes/ketones. DADH is the member of the short-chain dehydrogenases/reductases family (SDR) for which the largest amount of biochemical data has been gathered during the last three decades. The crystal structures of one binary form (NAD+) and three ternary complexes with NAD+.acetone, NAD+.3-pentanone and NAD+.cyclohexanone were solved at 2.4, 2.2, 1. 4 and 1.6 A resolution, respectively. From the molecular interactions observed, the reaction mechanism could be inferred. The structure of DADH undergoes a conformational change in order to bind the coenzyme. Furthermore, upon binding of the ketone, a region that was disordered in the apo form (186-191) gets stabilized and closes the active site cavity by creating either a small helix (NAD+. acetone, NAD+.3-pentanone) or an ordered loop (NAD+.cyclohexanone). The active site pocket comprises a hydrophobic bifurcated cavity which explains why the enzyme is more efficient in oxidizing secondary aliphatic alcohols (preferably R form) than primary ones. Difference Fourier maps showed that the ketone inhibitor molecule has undergone a covalent reaction with the coenzyme in all three ternary complexes. Due to the presence of the positively charged ring of the coenzyme (NAD+) and the residue Lys155, the amino acid Tyr151 is in its deprotonated (tyrosinate) state at physiological pH. Tyr151 can subtract a proton from the enolic form of the ketone and catalyze a nucleophilic attack of the Calphaatom to the C4 position of the coenzyme creating an NAD-ketone adduct. The binding of these NAD-ketone adducts to DADH accounts for the inactivation of the enzyme. The catalytic reaction proceeds in a similar way, involving the same amino acids as in the formation of the NAD-ketone adduct. The p Kavalue of 9-9.5 obtained by kinetic measurements on apo DADH can be assigned to a protonated Tyr151 which is converted to an unprotonated tyrosinate (p Ka7.6) by the influence of the positively charged nicotinamide ring in the binary enzyme-NAD+form. pH independence during the release of NADH from the binary complex enzyme-NADH can be explained by either a lack of electrostatic interaction between the coenzyme and Tyr151 or an apparent p Kavalue for this residue higher than 10.0.
果蝇乙醇脱氢酶(DADH)是一种依赖烟酰胺腺嘌呤二核苷酸(NAD⁺)的酶,可催化醇类氧化为醛/酮。DADH是短链脱氢酶/还原酶家族(SDR)的成员,在过去三十年中已积累了大量关于该家族的生化数据。分别以2.4、2.2、1.4和1.6埃的分辨率解析了一种二元形式(NAD⁺)以及与NAD⁺、丙酮、3-戊酮和环己酮形成的三种三元复合物的晶体结构。从观察到的分子相互作用中,可以推断出反应机制。DADH的结构会发生构象变化以结合辅酶。此外,酮类物质结合后,脱辅基形式下无序的区域(186 - 191)会变得稳定,并通过形成一个小螺旋(NAD⁺ - 丙酮、NAD⁺ - 3 - 戊酮)或一个有序环(NAD⁺ - 环己酮)来封闭活性位点腔。活性位点口袋包含一个疏水性分叉腔,这解释了为什么该酶氧化仲脂肪醇(优选R型)比伯醇更有效。差分傅里叶图显示,在所有三种三元复合物中,酮抑制剂分子与辅酶发生了共价反应。由于辅酶(NAD⁺)带正电荷的环和赖氨酸残基Lys155的存在,氨基酸酪氨酸151(Tyr151)在生理pH下处于去质子化(酪氨酸盐)状态。Tyr151可以从酮的烯醇形式中夺取一个质子,并催化α碳原子对辅酶C4位置的亲核攻击,形成NAD - 酮加合物。这些NAD - 酮加合物与DADH的结合导致酶失活。催化反应以类似的方式进行,涉及与形成NAD - 酮加合物相同的氨基酸。通过对脱辅基DADH进行动力学测量得到的9 - 9.5的pKa值可归因于质子化的Tyr151,在二元酶 - NAD⁺形式中,由于带正电荷的烟酰胺环的影响,它会转化为未质子化的酪氨酸盐(pKa 7.6)。从二元复合酶 - NADH释放NADH过程中的pH独立性可以通过辅酶与Tyr151之间缺乏静电相互作用或该残基的表观pKa值高于10.0来解释。
