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  • Direct observation of structurally encoded metal discrimination and ether bond formation in a heterodinuclear metalloprotein.

Direct observation of structurally encoded metal discrimination and ether bond formation in a heterodinuclear metalloprotein.

Proceedings of the National Academy of Sciences of the United States of America (2013-10-09)
Julia J Griese, Katarina Roos, Nicholas Cox, Hannah S Shafaat, Rui M M Branca, Janne Lehtiö, Astrid Gräslund, Wolfgang Lubitz, Per E M Siegbahn, Martin Högbom
ABSTRACT

Although metallocofactors are ubiquitous in enzyme catalysis, how metal binding specificity arises remains poorly understood, especially in the case of metals with similar primary ligand preferences such as manganese and iron. The biochemical selection of manganese over iron presents a particularly intricate problem because manganese is generally present in cells at a lower concentration than iron, while also having a lower predicted complex stability according to the Irving-Williams series (Mn(II) < Fe(II) < Ni(II) < Co(II) < Cu(II) > Zn(II)). Here we show that a heterodinuclear Mn/Fe cofactor with the same primary protein ligands in both metal sites self-assembles from Mn(II) and Fe(II) in vitro, thus diverging from the Irving-Williams series without requiring auxiliary factors such as metallochaperones. Crystallographic, spectroscopic, and computational data demonstrate that one of the two metal sites preferentially binds Fe(II) over Mn(II) as expected, whereas the other site is nonspecific, binding equal amounts of both metals in the absence of oxygen. Oxygen exposure results in further accumulation of the Mn/Fe cofactor, indicating that cofactor assembly is at least a two-step process governed by both the intrinsic metal specificity of the protein scaffold and additional effects exerted during oxygen binding or activation. We further show that the mixed-metal cofactor catalyzes a two-electron oxidation of the protein scaffold, yielding a tyrosine-valine ether cross-link. Theoretical modeling of the reaction by density functional theory suggests a multistep mechanism including a valyl radical intermediate.

MATERIALS
Product Number
Brand
Product Description

Sigma-Aldrich
Diethyl ether, for residue analysis, JIS 5000
Sigma-Aldrich
Diethyl ether, ≥99.5%
Sigma-Aldrich
Diethyl ether, JIS special grade, ≥99.5%
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Manganese, powder, ≥99.9% trace metals basis
Sigma-Aldrich
Diethyl ether, contains 1 ppm BHT as inhibitor, anhydrous, ≥99.7%
Sigma-Aldrich
Manganese, powder, −325 mesh, ≥99% trace metals basis
Sigma-Aldrich
Manganese, chips, thickness <2.0 mm, 99%
Supelco
Diethyl ether, analytical standard
Sigma-Aldrich
Diethyl ether, JIS 300, ≥99.5%, for residue analysis
Sigma-Aldrich
Diethyl ether, SAJ first grade, ≥99.0%
Sigma-Aldrich
Diethyl ether, JIS 1000, ≥99.5%, for residue analysis
Sigma-Aldrich
Diethyl ether, suitable for HPLC, ≥99.9%, inhibitor-free
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Diethyl ether, ACS reagent, ≥98.0%, contains ≤2% ethanol and ≤10ppm BHT as inhibitor
Sigma-Aldrich
Diethyl ether, anhydrous, ACS reagent, ≥99.0%, contains BHT as inhibitor
Sigma-Aldrich
Diethyl ether, contains BHT as inhibitor, puriss. p.a., ACS reagent, reag. ISO, reag. Ph. Eur., ≥99.8% (GC)
Sigma-Aldrich
Diethyl ether, ACS reagent, anhydrous, ≥99.0%, contains BHT as inhibitor
Sigma-Aldrich
Diethyl ether, puriss., contains ~5 mg/L 2,6-di-tert.-butyl-4-methylphenol as stabilizer, meets analytical specification of Ph. Eur., BP, ≥99.5% (GC)
Sigma-Aldrich
Diethyl ether, reagent grade, ≥98%, contains ≤2% ethanol and ≤10ppm BHT as inhibitor