Dipartimento di Chimica "Ugo Schiff", Università di Firenze, Via della Lastruccia 3, I-50019 Sesto Fiorentino-FI, Italy.
J Struct Biol. 2012 Dec;180(3):563-71. doi: 10.1016/j.jsb.2012.08.007. Epub 2012 Aug 31.
Key amino acid residues of the salicylate 1,2-dioxygenase (SDO), an iron (II) class III ring cleaving dioxygenase from Pseudaminobacter salicylatoxidans BN12, were selected, based on amino acid sequence alignments and structural analysis of the enzyme, and modified by site-directed mutagenesis to obtain variant forms with altered catalytic properties. SDO shares with 1-hydroxy-2-naphthoate dioxygenase (1H2NDO) its unique ability to oxidatively cleave monohydroxylated aromatic compounds. Nevertheless SDO is more versatile with respect to 1H2NDO and other known gentisate dioxygenases (GDOs) because it cleaves not only gentisate and 1-hydroxy-2-naphthoate (1H2NC) but also salicylate and substituted salicylates. Several enzyme variants of SDO were rationally designed to simulate 1H2NDO. The basic kinetic parameters for the SDO mutants L38Q, M46V, A85H and W104Y were determined. The enzyme variants L38Q, M46V, A85H demonstrated higher catalytic efficiencies toward 1-hydroxy-2-naphthoate (1H2NC) compared to gentisate. Remarkably, the enzyme variant A85H effectively cleaved 1H2NC but did not oxidize gentisate at all. The W104Y SDO mutant exhibited reduced reaction rates for all substrates tested. The crystal structures of the A85H and W104Y variants were solved and analyzed. The substitution of Ala85 with a histidine residue caused significant changes in the orientation of the loop containing this residue which is involved in the active site closing upon substrate binding. In SDO A85H this specific loop shifts away from the active site and thus opens the cavity favoring the binding of bulkier substrates. Since this loop also interacts with the N-terminal residues of the vicinal subunit, the structure and packing of the holoenzyme might be also affected.
关键的氨基酸残基的水杨酸 1,2-二氧化酶 (SDO),铁 (II) 类三环开裂双加氧酶从假单胞菌水杨酸氧化 BN12,选择,基于氨基酸序列比对和结构分析的酶,并通过定点突变修饰获得改变催化性质的变体形式。SDO 与 1-羟基-2-萘二羧酸 (1H2NDO) 共享其独特的能力,氧化裂解开环单羟基芳族化合物。然而,SDO 相对于 1H2NDO 和其他已知的龙胆二羧酸 (GDO) 更具多功能性,因为它不仅裂解龙胆酸和 1-羟基-2-萘酸 (1H2NC),而且裂解水杨酸和取代水杨酸。SDO 的几个酶变体被合理设计模拟 1H2NDO。SDO 突变体 L38Q、M46V、A85H 和 W104Y 的基本动力学参数被确定。酶变体 L38Q、M46V、A85H 对 1-羟基-2-萘二羧酸 (1H2NC) 的催化效率高于龙胆酸。值得注意的是,酶变体 A85H 有效地裂解 1H2NC,但根本不氧化龙胆酸。W104Y SDO 突变体表现出所有测试底物的反应速率降低。A85H 和 W104Y 变体的晶体结构被解决和分析。用组氨酸残基取代 Ala85 导致包含该残基的环的取向发生显著变化,该环在底物结合时参与活性位点的关闭。在 SDO A85H 中,这个特定的环从活性位点移开,从而打开空腔,有利于较大底物的结合。由于这个环也与相邻亚基的 N 端残基相互作用,因此全酶的结构和包装可能也受到影响。
