Tyson Kristin J, Davis Amanda N, Norris Jessica L, Bartolotti Libero J, Hvastkovs Eli G, Offenbacher Adam R
Department of Chemistry, East Carolina University, Greenville, North Carolina 27858, United States.
J Phys Chem Lett. 2020 Apr 2;11(7):2408-2413. doi: 10.1021/acs.jpclett.0c00614. Epub 2020 Mar 12.
Tyrosine and tryptophan play critical roles in facilitating proton-coupled electron transfer (PCET) processes essential to life. The local protein environment is anticipated to modulate the thermodynamics of amino acid radicals to achieve controlled, unidirectional PCET. Herein, square-wave voltammetry was employed to investigate the electrostatic effects on the redox properties of tryptophan in two variants of the protein azurin. Each variant contains a single redox-active tryptophan, W48 or W108, in a unique and buried protein environment. These tryptophan residues exhibit reversible square-wave voltammograms. A Pourbaix plot, representing the reduction potentials versus pH, is presented for the non-H-bonded W48, which has potentials comparable to those of tryptophan in solution. The reduction potentials of W108 are seen to be increased by more than 100 mV across the same pH range. Molecular dynamics shows that, despite its buried indole ring, the N-H of W108 hydrogen bonds with a water cluster, while W48 is completely excluded from interactions with water or polar groups. These redox properties provide insight into the role of the protein in tuning the reactivity of tryptophan radicals, a requirement for controlled biological PCET.
酪氨酸和色氨酸在促进生命所必需的质子耦合电子转移(PCET)过程中发挥着关键作用。预计局部蛋白质环境会调节氨基酸自由基的热力学,以实现可控的单向PCET。在此,采用方波伏安法研究了静电作用对蛋白质天青蛋白两种变体中色氨酸氧化还原性质的影响。每个变体在独特的埋藏蛋白质环境中都含有一个单一的氧化还原活性色氨酸,W48或W108。这些色氨酸残基呈现出可逆的方波伏安图。给出了非氢键结合的W48的Pourbaix图,其还原电位与溶液中色氨酸的还原电位相当。在相同的pH范围内,W108的还原电位增加了100多毫伏。分子动力学表明,尽管W108的吲哚环埋藏在内部,但其N-H与一个水簇形成氢键,而W48则完全被排除在与水或极性基团的相互作用之外。这些氧化还原性质有助于深入了解蛋白质在调节色氨酸自由基反应性方面的作用,这是可控生物PCET的一个必要条件。
