Department of Biochemistry, Molecular Biology and Biophysics and Center for Metals in Biocatalysis, University of Minnesota, Minneapolis, Minnesota 55455, United States.
Biochemistry. 2012 Nov 6;51(44):8743-54. doi: 10.1021/bi301114x. Epub 2012 Oct 29.
Homoprotocatechuate (HPCA; 3,4-dihydroxyphenylacetate or 4-carboxymethyl catechol) and O(2) bind in adjacent ligand sites of the active site Fe(II) of homoprotocatechuate 2,3-dioxygenase (FeHPCD). We have proposed that electron transfer from the chelated aromatic substrate through the Fe(II) to O(2) gives both substrates radical character. This would promote reaction between the substrates to form an alkylperoxo intermediate as the first step in aromatic ring cleavage. Several active site amino acids are thought to promote these reactions through acid/base chemistry, hydrogen bonding, and electrostatic interactions. Here the role of Tyr257 is explored by using the Tyr257Phe (Y257F) variant, which decreases k(cat) by about 75%. The crystal structure of the FeHPCD-HPCA complex has shown that Tyr257 hydrogen bonds to the deprotonated C2-hydroxyl of HPCA. Stopped-flow studies show that at least two reaction intermediates, termed Y257F(Int1)(HPCA) and Y257F(Int2)(HPCA), accumulate during the Y257F-HPCA + O(2) reaction prior to formation of the ring-cleaved product. Y257F(Int1)(HPCA) is colorless and is formed as O(2) binds reversibly to the HPCA−enzyme complex. Y257F(Int2)(HPCA) forms spontaneously from Y257F(Int1)(HPCA) and displays a chromophore at 425 nm (ε(425) = 10 500 M(−1) cm(−1)). Mössbauer spectra of the intermediates trapped by rapid freeze quench show that both intermediates contain Fe(II). The lack of a chromophore characteristic of a quinone or semiquinone form of HPCA, the presence of Fe(II), and the low O(2) affinity suggest that Y257F(Int1)(HPCA) is an HPCA-Fe(II)-O(2) complex with little electron delocalization onto the O(2). In contrast, the intense spectrum of Y257F(Int2)(HPCA) suggests the intermediate is most likely an HPCA quinone-Fe(II)-(hydro)peroxo species. Steady-state and transient kinetic analyses show that steps of the catalytic cycle are slowed by as much as 100-fold by the mutation. These effects can be rationalized by a failure of Y257F to facilitate the observed distortion of the bound HPCA that is proposed to promote transfer of one electron to O(2).
原儿茶酸(HPCA;3,4-二羟基苯乙酸或 4-羧甲基儿茶酚)和 O(2)结合在同型原儿茶酸 2,3-双加氧酶(FeHPCD)活性部位的相邻配体位置。我们提出,从螯合芳基底物通过 Fe(II)到 O(2)的电子转移赋予两个底物自由基特征。这将促进底物之间的反应,形成烷基过氧中间体,作为芳环裂解的第一步。一些活性部位氨基酸被认为通过酸/碱化学、氢键和静电相互作用来促进这些反应。在这里,通过使用 Tyr257Phe (Y257F)变体探索 Tyr257 的作用,该变体使 k(cat)降低约 75%。FeHPCD-HPCA 复合物的晶体结构表明 Tyr257 与 HPCA 的去质子 C2-羟基氢键结合。停流研究表明,在 Y257F-HPCA + O(2)反应期间,至少有两个反应中间体,称为 Y257F(Int1)(HPCA)和 Y257F(Int2)(HPCA),在形成环裂解产物之前积累。Y257F(Int1)(HPCA)是无色的,并且在 O(2)可逆结合到 HPCA-酶复合物时形成。Y257F(Int2)(HPCA)自发地从 Y257F(Int1)(HPCA)形成,并在 425nm 处显示出色原体(ε(425)=10500M(−1)cm(−1))。通过快速冷冻淬火捕获的中间体的穆斯堡尔光谱表明,两种中间体都含有 Fe(II)。缺乏 HPCA 的醌或半醌形式的特征色原体、Fe(II)的存在以及低 O(2)亲和力表明 Y257F(Int1)(HPCA)是一种 HPCA-Fe(II)-O(2)复合物,电子向 O(2)的离域作用很小。相比之下,Y257F(Int2)(HPCA)的强烈光谱表明该中间体很可能是 HPCA 醌-Fe(II)-(氢)过氧物种。稳态和瞬态动力学分析表明,突变使催化循环的步骤减慢了多达 100 倍。这些影响可以通过 Y257F 不能促进所观察到的结合 HPCA 的变形来合理化,该变形被提议促进向 O(2)转移一个电子。
