一项使用氧气和过氧化氢作为铁氧化剂的人H链铁蛋白矿物核心的穆斯堡尔对比研究。
A comparative Mössbauer study of the mineral cores of human H-chain ferritin employing dioxygen and hydrogen peroxide as iron oxidants.
作者信息
Bou-Abdallah Fadi, Carney Elissa, Chasteen N Dennis, Arosio Paolo, Viescas Arthur J, Papaefthymiou Georgia C
机构信息
Department of Chemistry, University of New Hampshire, Durham, NH 03824, USA.
出版信息
Biophys Chem. 2007 Nov;130(3):114-21. doi: 10.1016/j.bpc.2007.08.003. Epub 2007 Aug 22.
Ferritins are ubiquitous iron storage and detoxification proteins distributed throughout the plant and animal kingdoms. Mammalian ferritins oxidize and accumulate iron as a ferrihydrite mineral within a shell-like protein cavity. Iron deposition utilizes both O(2) and H(2)O(2) as oxidants for Fe(2+) where oxidation can occur either at protein ferroxidase centers or directly on the surface of the growing mineral core. The present study was undertaken to determine whether the nature of the mineral core formed depends on the protein ferroxidase center versus mineral surface mechanism and on H(2)O(2) versus O(2) as the oxidant. The data reveal that similar cores are produced in all instances, suggesting that the structure of the core is thermodynamically, not kinetically controlled. Cores averaging 500 Fe/protein shell and diameter approximately 2.6 nm were prepared and exhibited superparamagnetic blocking temperatures of 19 and 22 K for the H(2)O(2) and O(2) oxidized samples, respectively. The observed blocking temperatures are consistent with the unexpectedly large effective anisotropy constant K(eff)=312 kJ/m(3) recently reported for ferrihydrite nanoparticles formed in reverse micelles [E.L. Duarte, R. Itri, E. Lima Jr., M.S. Batista, T.S. Berquó and G.F. Goya, Large Magnetic Anisotropy in ferrihydrite nanoparticles synthesized from reverse micelles, Nanotechnology 17 (2006) 5549-5555.]. All ferritin samples exhibited two magnetic phases present in nearly equal amounts and ascribed to iron spins at the surface and in the interior of the nanoparticle. At 4.2 K, the surface spins exhibit hyperfine fields, H(hf), of 436 and 445 kOe for the H(2)O(2) and O(2) samples, respectively. As expected, the spins in the interior of the core exhibit larger H(hf) values, i.e. 478 and 486 kOe for the H(2)O(2) and O(2) samples, respectively. The slightly smaller hyperfine field distribution DH(hf) for both surface (78 kOe vs. 92 kOe) and interior spins (45 kOe vs. 54 kOe) of the O(2) sample compared to the H(2)O(2) samples implies that the former is somewhat more crystalline.
铁蛋白是普遍存在的铁储存和解毒蛋白,分布于整个植物和动物界。哺乳动物铁蛋白将铁氧化并以水铁矿矿物的形式积累在壳状蛋白质腔内。铁沉积利用O₂和H₂O₂作为Fe²⁺的氧化剂,氧化可发生在蛋白质铁氧化酶中心或直接在生长的矿物核表面。本研究旨在确定所形成的矿物核的性质是否取决于蛋白质铁氧化酶中心与矿物表面机制,以及取决于H₂O₂与O₂作为氧化剂。数据显示,在所有情况下都产生了相似的核,这表明核的结构是由热力学控制,而非动力学控制。制备了平均每蛋白质壳含500个铁原子且直径约为2.6纳米的核,对于H₂O₂和O₂氧化的样品,其超顺磁阻塞温度分别为19 K和22 K。观察到的阻塞温度与最近报道的在反胶束中形成的水铁矿纳米颗粒出人意料的大有效各向异性常数K(eff)=312 kJ/m³一致[E.L. Duarte, R. Itri, E. Lima Jr., M.S. Batista, T.S. Berquó和G.F. Goya,反胶束合成的水铁矿纳米颗粒中的大磁各向异性,《纳米技术》17 (2006) 5549 - 5555]。所有铁蛋白样品都表现出两种磁相,其含量几乎相等,分别归因于纳米颗粒表面和内部的铁自旋。在4.2 K时,对于H₂O₂和O₂样品,表面自旋的超精细场H(hf)分别为436和445 kOe。正如预期的那样,核内部的自旋表现出更大的H(hf)值,即对于H₂O₂和O₂样品分别为478和486 kOe。与H₂O₂样品相比,O₂样品的表面(78 kOe对92 kOe)和内部自旋(45 kOe对54 kOe)的超精细场分布DH(hf)略小,这意味着前者的结晶度略高。
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