Hoffman Brian M, Dean Dennis R, Seefeldt Lance C
Department of Chemistry, Northwestern University, 2145 Sheridan Road, Tech K148, Evanston, Illinois 60208, USA.
Acc Chem Res. 2009 May 19;42(5):609-19. doi: 10.1021/ar8002128.
"Nitrogen fixation", the reduction of dinitrogen (N2) to two ammonia (NH3) molecules, by the Mo-dependent nitrogenase is essential for all life. Despite four decades of research, a daunting number of unanswered questions about the mechanism of nitrogenase activity make it the "Everest of enzymes". This Account describes our efforts to climb one "face" of this mountain by meeting two interdependent challenges central to determining the mechanism of biological N2 reduction. The first challenge is to determine the reaction pathway: the composition and structure of each of the substrate-derived moieties bound to the catalytic FeMo cofactor (FeMo-co) of the molybdenum-iron (MoFe) protein of nitrogenase. To overcome this challenge, it is necessary to discriminate between the two classes of potential reaction pathways: (1) a "distal" (D) pathway, in which H atoms add sequentially at a single N or (2) an "alternating" (A) pathway, in which H atoms add alternately to the two N atoms of N2. Second, it is necessary to characterize the dynamics of conversion among intermediates within the accepted Lowe-Thorneley kinetic scheme for N2 reduction. That goal requires an experimental determination of the number of electrons and protons delivered to the MoFe protein as well as their "inventory", a partition into those residing on each of the reaction components and released as H2 or NH3. The principal obstacle to this "climb" has been the inability to generate N2 reduction intermediates for characterization. A combination of genetic, biochemical, and spectroscopic approaches recently overcame this obstacle. These experiments identified one of the four-iron Fe-S faces of the active-site FeMo-co as the specific site of reactivity, indicated that the side chain of residue alpha70V controls access to this face, and supported the involvement of the side chain of residue alpha195H in proton delivery. We can now freeze-quench trap N2 reduction pathway intermediates and use electron-nuclear double resonance (ENDOR) and electron spin-echo envelope modulation (ESEEM) spectroscopies to characterize them. However, even successful trapping of a N2 reduction intermediate occurs without synchronous electron delivery to the MoFe protein. As a result, the number of electrons and protons, n, delivered to MoFe during its formation is unknown. To determine n and the electron inventory, we initially employed ENDOR spectroscopy to analyze the substrate moiety bound to the FeMo-co and 57Fe within the cofactor. Difficulties in using that approach led us to devise a robust kinetic protocol for determining n of a trapped intermediate. This Account describes strategies that we have formulated to bring this "face" of the nitrogenase mechanism into view and afford approaches to its climb. Although the summit remains distant, we look forward to continued progress in the ascent.
“固氮作用”,即将双氮(N₂)还原为两个氨(NH₃)分子,由钼依赖型固氮酶催化,这对所有生命来说都是必不可少的。尽管经过了四十年的研究,但关于固氮酶活性机制仍有大量未解决的问题,使其成为“酶中之珠穆朗玛峰”。本综述描述了我们通过应对两个相互依存的关键挑战来攀登这座“山峰”一面的努力,这两个挑战对于确定生物固氮还原机制至关重要。第一个挑战是确定反应途径:与固氮酶钼铁(MoFe)蛋白的催化铁钼辅因子(FeMo-co)结合的每个底物衍生部分的组成和结构。为了克服这一挑战,有必要区分两类潜在的反应途径:(1)“远端”(D)途径,其中氢原子在单个氮原子上依次添加;(2)“交替”(A)途径,其中氢原子交替添加到N₂的两个氮原子上。其次,有必要在公认的用于N₂还原的Lowe-Thorneley动力学方案中表征中间体之间转化的动力学。该目标需要通过实验确定传递到MoFe蛋白的电子和质子的数量及其“存量”,即将其分配到每个反应组分上并以H₂或NH₃形式释放的部分。这一“攀登”的主要障碍一直是无法生成用于表征的N₂还原中间体。最近,通过遗传、生化和光谱学方法的结合克服了这一障碍。这些实验确定了活性位点FeMo-co的四个铁Fe-S面之一为反应的特定位点,表明α70V残基的侧链控制着对该面的 access,并且支持α195H残基的侧链参与质子传递。我们现在可以冷冻淬灭捕获N₂还原途径中间体,并使用电子-核双共振(ENDOR)和电子自旋回波包络调制(ESEEM)光谱对其进行表征。然而,即使成功捕获了N₂还原中间体,电子也不会同步传递到MoFe蛋白。因此,在其形成过程中传递到MoFe的电子和质子的数量n是未知的。为了确定n和电子存量,我们最初采用ENDOR光谱分析与FeMo-co和辅因子内的⁵⁷Fe结合的底物部分。使用该方法的困难促使我们设计了一种稳健的动力学方案来确定捕获中间体的n。本综述描述了我们制定的策略,以揭示固氮酶机制的这一“面”并提供攀登途径。尽管顶峰仍遥不可及,但我们期待在攀登过程中持续取得进展。
