Reaction of Oxygen with 6-Hydroxydopamine Catalyzed by Cu, Fe, Mn, and V Complexes: Identification of a Thermodynamic Window for Effective Metal Catalysis

In the autoxidation of 6-hydroxydopamine, we investigated the reactivity of metals and metal complexes with a range of abilities to catalyse the reaction with oxygen. Comparing the catalytic effectiveness of aquo metals at pH 7.4, copper accelerated autoxidation 61-fold, iron 24-fold, manganese 7.3-...

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Bibliographic Details
Published in:Archives of biochemistry and biophysics 2001-05, Vol.389 (1), p.22-30
Main Authors: Bandy, Brian, Walter, Patrick B., Moon, Jym, Davison, Allan J.
Format: Article
Language:English
Subjects:
6-hydroxydopamine oxidation
Adenosine Diphosphate - chemistry
Bromides - chemistry
Buffers
Catalysis
copper
Copper - chemistry
Deferoxamine - chemistry
dioxygen
Edetic Acid - chemistry
free radical
Histidine - chemistry
Hydrogen-Ion Concentration
iron
Iron - chemistry
Ligands
manganese
Manganese - chemistry
metal:ligand complex
Osmolar Concentration
Oxidation-Reduction
Oxidopamine - chemistry
Oxygen - chemistry
Phytic Acid - chemistry
reduction potential
Sodium Compounds - chemistry
Thermodynamics
transition metal catalysis
vanadium
Vanadium - chemistry
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Summary:In the autoxidation of 6-hydroxydopamine, we investigated the reactivity of metals and metal complexes with a range of abilities to catalyse the reaction with oxygen. Comparing the catalytic effectiveness of aquo metals at pH 7.4, copper accelerated autoxidation 61-fold, iron 24-fold, manganese 7.3-fold, and vanadium 5.7-fold. Copper was thus the most effective catalyst despite being the weakest oxidant, indicating reduction of oxygen as rate limiting. EDTA, which decreases the reduction potential of Fe(III)/Fe(II), increased catalysis by iron 74% to almost that of aquo copper. Conversely, EDTA inhibited catalysis by copper, manganese, and vanadium. Desferrioxamine strongly inhibited catalysis by all of the metals. Histidine prevented catalysis by copper, accelerated catalysis by iron (43%), and had little effect on catalysis by manganese or vanadium. ADP and phytate inhibited catalysis by iron and manganese (50% or more), accelerated catalysis by vanadium (10–27%), and had no effect on catalysis by copper. The effects of the ligands largely reflected their influence on the reduction potential of the metal. Accordingly, addition of NaBr, which increases the reduction potential of Cu(II)/Cu(I), inhibited by 50%. In contrast, Na2SO4 augmented catalysis by copper 3-fold. Consistent with effects of OH− on reduction potentials and on metal coordination to 6-hydroxydopamine, an increase in pH to 8.0 decreased catalysis by copper and iron, but increased that of manganese 10-fold. In conclusion, the catalytic effectiveness of the metal–ligand complexes are largely attributable to their reduction potential, with steric accessibility playing secondary roles. The results delineate a window of catalytically effective potentials suitable for facile reduction and reoxidation by oxygen. By extension the results identify factors determining the pro- and antioxidant roles of ligands in metal mediated reduction of oxygen.
ISSN:0003-9861
1096-0384
DOI:10.1006/abbi.2001.2285