Department of Biochemistry and Molecular Biology, Oregon Health and Science University , Portland, Oregon 97239, United States.
Department of Biochemistry, University of Utah , Salt Lake City, Utah 84112, United States.
J Am Chem Soc. 2017 Apr 5;139(13):4846-4853. doi: 10.1021/jacs.7b00236. Epub 2017 Mar 27.
Arginine kinase (AK), which is a member of the phosphagen kinase family, serves as a model system for studying the structural and dynamic determinants of biomolecular enzyme catalysis of all major states involved of the enzymatic cycle. These states are the apo state (substrate free), the Michaelis complex analogue AK:Arg:Mg·AMPPNP (MCA), a product complex analogue AK:pAIE:Mg·ADP (PCA), and the transition state analogue AK:Arg:Mg·ADP:NO (TSA). The conformational dynamics of these states have been studied by NMR relaxation dispersion measurements of the methyl groups of the Ile, Leu, and Val residues at two static magnetic fields. Although all states undergo significant amounts of μs-ms time scale dynamics, only the MCA samples a dominant excited state that resembles the TSA, as evidenced by the strong correlation between the relaxation dispersion derived chemical shift differences Δω and the equilibrium chemical shift differences Δδ of these states. The average lifetime of the MCA is 36 ms and the free energy difference to the TSA-like form is 8.5 kJ/mol. It is shown that the conformational energy landscape of the Michaelis complex analogue is shaped in a way that at room temperature it channels passage to the transition state, thereby determining the rate-limiting step of the phosphorylation reaction of arginine. Conversely, relaxation dispersion experiments of the TSA reveal that it samples the structures of the Michaelis complex analogue or the apo state as its dominant excited state. This reciprocal behavior shows that the free energy of the TSA, with all ligands bound, is lower by only about 8.9 kJ/mol than that of the Michaelis or apo complex conformations with the TSA ligands present.
精氨酸激酶(AK)是磷酸肌酸激酶家族的成员,可作为研究生物分子酶催化所有主要酶循环状态下结构和动态决定因素的模型系统。这些状态是无配体状态(无底物)、米氏复合物类似物 AK:Arg:Mg·AMPPNP(MCA)、产物复合物类似物 AK:pAIE:Mg·ADP(PCA)和过渡态类似物 AK:Arg:Mg·ADP:NO(TSA)。这些状态的构象动力学已经通过在两个静态磁场下对 Ile、Leu 和 Val 残基的甲基进行 NMR 弛豫分散测量来研究。尽管所有状态都经历了大量的 μs-ms 时间尺度动力学,但只有 MCA 样品出一个类似于 TSA 的主导激发态,这可以通过弛豫分散得出的化学位移差 Δω与这些状态的平衡化学位移差 Δδ之间的强相关性来证明。MCA 的平均寿命为 36 毫秒,与 TSA 样形式的自由能差为 8.5 kJ/mol。结果表明,米氏复合物类似物的构象能谱以这样的方式形成,即在室温下,它会引导反应过渡到过渡态,从而决定精氨酸磷酸化反应的限速步骤。相反,TSA 的弛豫分散实验表明,它以 Michaelis 复合物类似物或无配体状态作为其主导激发态来采样结构。这种相互作用表明,与具有 TSA 配体的 Michaelis 或无配体复合物构象相比,所有配体结合的 TSA 的自由能仅低约 8.9 kJ/mol。
