The effects of metal cofactors on the reactivity of quercetin 2,4-dioxygenase: synthetic model studies with M(II)-complexes (M = Mn, Co, Ni, Cu, Zn) and assessment of the regulatory factors in catalytic efficacy.

This paper demonstrates the metal ion effects on the quercetin 2,4-dioxygenase (2,4-QD)-like reactivity. For this purpose, a series of five metal(II)-acetato complexes [M(L)(OAc)] {M = Mn (1OAc), Co (2OAc), Ni (3OAc), Cu (4OAc), Zn (5OAc); OAc = acetate} supported with a newly designed NO-donor carboxylato ligand L {L = 2-((benzyl((6'-methyl-[2,2'-bipyridin]-6-yl)methyl)amino)methyl)benzoate} has been synthesised as models for the active sites of M-substituted 2,4-QDs. The enzyme-substrate (ES) model complexes [M(L)(fla)] {M = Mn (1fla), Co (2fla), Ni (3fla), Cu (4fla), Zn (5fla); flaH = flavonol} have been synthesised by reacting flaH with their corresponding acetate-bound complexes in basic conditions. Detailed physicochemical properties of all the compounds are reported. Furthermore, single-crystal X-ray diffractions have been done to determine the structures of the compounds 2OAc·2H2O, 3OAc, 4OAc·CH2Cl2·2H2O, 5OAc·2H2O and 2fla·MeOH. The enzymatic reactivities of complexes 1OAc-5OAc towards the dioxygenation of flavonol have been explored in detail. All the complexes effectively catalyse the oxygenative degradation of flavonol in ,-dimethylformamide (DMF) medium at 70 °C under multiple-turnover conditions and produce enzyme-type products. Kinetic investigations were performed to see the metal ions' effects on reactivity. The reaction rates vary with the metal ions, showing the order Co > Ni > Zn > Mn > Cu. The studies reveal that the reactivities of the [M(L)(OAc)] complexes are governed primarily by three factors the ES adduct formation constant (), the redox potential () of the bound fla/fla˙ couple, and the degree of delocalisation of the fla˙ radical with the metal electrons, which are drastically influenced by the M ions. In the mechanistic interpretation, a single-electron transfer (SET) from the bound-flavonolate to dioxygen has been proposed to generate the catalytically important "M(II)-fla˙" radical and superoxide ion, which react further to bring about the dioxygenation reaction. The identification of the metal(II)-bound flavonoxy radical intermediate for the case of cobalt using EPR spectroscopy and the detection of superoxide ion by NBT test and EPR spin-trapping experiment (DMPO test) are remarkable in envisaging the reaction pathway.