Treffry A, Zhao Z, Quail M A, Guest J R, Harrison P M
Department of Molecular Biology and Biotechnology, Krebs Institute, University of Sheffield, U.K.
Biochemistry. 1997 Jan 14;36(2):432-41. doi: 10.1021/bi961830l.
The ferroxidase activity of human ferritin has previously been associated with a diiron site situated centrally within the four-helix bundle of H-type chains (HuHF). However, direct information about the site of Fe(II) binding has been lacking, and events between Fe(II) binding and its oxidation have not previously been studied. A sequential stopped-flow assay has now been developed to enable the dissection of binding and oxidation. It depends on the ability of 1,10-phenanthroline to complex protein-bound Fe(II) and to distinguish it from the more immediately available free Fe(II). This approach, aided by the use of site-directed variants, indicates that in HuHF and the non-heme ferritin of Escherichia coli the first 48 Fe(II) atoms/molecule added are bound and oxidized at the dinuclear centers. At a constant iron concentration, the rate of Fe(II) oxidation was maximal for additions of 2 Fe(II) atoms/subunit, consistent with a two-electron oxidation of the Fe(II) pair. Although, at low Fe(II)/protein ratios, no cooperativity in Fe(II) binding was observed; a preferred order of binding was deduced [Fe(II) binding first at site A and then at site B]. Binding of Fe(II) at both sites was essential for fast oxidation. Modification of site A ligands resulted in slow iron binding and slow oxidation. Modification of site B did not prevent Fe(II) binding at site A but greatly reduced its oxidation rate. These differences may mean that dioxygen is initially bound to Fe(II) at site B.
人铁蛋白的亚铁氧化酶活性此前一直与位于H型链(HuHF)四螺旋束中心的双核位点相关。然而,关于亚铁结合位点的直接信息一直缺乏,并且亚铁结合与其氧化之间的过程此前也未被研究。现在已开发出一种连续停流测定法来解析结合和氧化过程。它依赖于1,10 - 菲咯啉与蛋白结合的亚铁络合的能力,并将其与更易获得的游离亚铁区分开来。这种方法,借助定点变异体,表明在HuHF和大肠杆菌的非血红素铁蛋白中,添加的最初48个亚铁原子/分子在双核中心结合并被氧化。在铁浓度恒定的情况下,添加2个亚铁原子/亚基时亚铁氧化速率最大,这与亚铁对的双电子氧化一致。尽管在低亚铁/蛋白比例下,未观察到亚铁结合的协同性;但推断出了一个优先结合顺序[亚铁首先在位点A结合,然后在位点B结合]。亚铁在两个位点的结合对于快速氧化至关重要。位点A配体的修饰导致铁结合缓慢和氧化缓慢。位点B的修饰并未阻止亚铁在位点A的结合,但大大降低了其氧化速率。这些差异可能意味着双氧最初在位点B与亚铁结合。
