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炭疽热水肿因子催化 ATP 向 cAMP 转化的化学机制的经验价电子键模拟。

Empirical valence bond simulations of the chemical mechanism of ATP to cAMP conversion by anthrax edema factor.

机构信息

Department of Chemistry, Loyola University Chicago, Chicago, Illinois 60660, USA.

出版信息

Biochemistry. 2013 Apr 16;52(15):2672-82. doi: 10.1021/bi400088y. Epub 2013 Apr 2.

Abstract

The two-metal catalysis by the adenylyl cyclase domain of the anthrax edema factor toxin was simulated using the empirical valence bond (EVB) quantum mechanical/molecular mechanical approach. These calculations considered the energetics of the nucleophile deprotonation and the formation of a new P-O bond in aqueous solution and in the enzyme-substrate complex present in the crystal structure models of the reactant and product states of the reaction. Our calculations support a reaction pathway that involves metal-assisted transfer of a proton from the nucleophile to the bulk aqueous solution followed by subsequent formation of an unstable pentavalent intermediate that decomposes into cAMP and pyrophosphate (PPi). This pathway involves ligand exchange in the first solvation sphere of the catalytic metal. At 12.9 kcal/mol, the barrier for the last step of the reaction, the cleavage of the P-O bond to PPi, corresponds to the highest point on the free energy profile for this reaction pathway. However, this energy is too close to the value of 11.4 kcal/mol calculated for the barrier of the nucleophilic attack step to reach a definitive conclusion about the rate-limiting step. The calculated reaction mechanism is supported by reasonable agreement between the experimental and calculated catalytic rate constant decrease caused by the mutation of the active site lysine 346 to arginine.

摘要

采用经验价键(EVB)量子力学/分子力学方法模拟了炭疽水肿因子毒素的腺苷酸环化酶结构域的双金属催化作用。这些计算考虑了亲核试剂去质子化和在水溶液中以及在反应的反应物和产物状态的晶体结构模型中存在的酶-底物复合物中新 P-O 键形成的能量。我们的计算支持一种反应途径,其中涉及金属辅助质子从亲核试剂转移到体相水溶液中,随后形成不稳定的五价中间体,该中间体分解为 cAMP 和焦磷酸(PPi)。该途径涉及催化金属的第一溶剂化层中的配体交换。在 12.9 kcal/mol 处,反应的最后一步,即 P-O 键裂解为 PPi 的能垒,对应于该反应途径自由能图上的最高点。然而,由于亲核攻击步骤的能垒计算为 11.4 kcal/mol,这个能量与计算值太接近,无法得出关于限速步骤的明确结论。计算出的反应机制得到了合理的支持,即活性位点赖氨酸 346 突变为精氨酸导致实验和计算的催化速率常数下降之间存在合理的一致性。

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