Data di Pubblicazione:
2019
Abstract:
The aim of mimicking enzyme activity
represents an important motivation for the development of
new catalysts. A challenging objective is the development of
chiral complexes for bioinspired enantioselective oxidation
reactions. Herein, we report a new chiral dinuclear copper(II)
complex based on a m-xylyl-bis(histidine) ligand (mXHI) as a
biomimetic catalyst for tyrosinase and catechol oxidase. The
new ligand improves a previous system also containing two
tridentate N3 units derived from L-histidine that were
connected by a short, rigid ethanediamine bridge. In mXHI
the bridge is provided by the more extended m-xylyl moiety. The dicopper(II) complex [Cu2(mXHI)]4+ was studied as a
catalyst for stereoselective oxidations of enantiomeric couples of chiral catechols of biological interest (L/D-dopa, L/D-dopa
methyl ester, and (R/S)-norepinephrine), showing excellent discrimination capability, particularly for the methyl esters of dopa
enantiomers. The catechol oxidation was studied in acetate buffer as slightly acidic medium, and a role of acetate as bridging
ligand between the two coppers, preorganizing the dinuclear center in a more catalytic efficient structure, could be established.
The oxidation of β-naphthol and 3,5-ditertbutylphenol was studied as a model monophenolase reaction. The oxidation proceeds
stoichiometrically, and the partial incorporation of 18O into β-naphthol when the reaction was performed using 18O2 suggests
the existence of two competitive reaction pathways, a genuine monooxygenase mechanism and a radical pathway. However, the
more challenging reaction on derivatives of L-/D-tyrosine did not lead to the desired monooxygenase product but only to
products of radical oxidation. Complex [Cu2(mXHI)]4+ was also used for the catalytic sulfoxidation of thioanisole in the
presence of hydroxylamine as cosubstrate, in a preliminary attempt to model the reaction of external monooxygenases. The
reaction proceeds with 25 turnovers, but the enantiomeric excess of sulfoxide was modest.
represents an important motivation for the development of
new catalysts. A challenging objective is the development of
chiral complexes for bioinspired enantioselective oxidation
reactions. Herein, we report a new chiral dinuclear copper(II)
complex based on a m-xylyl-bis(histidine) ligand (mXHI) as a
biomimetic catalyst for tyrosinase and catechol oxidase. The
new ligand improves a previous system also containing two
tridentate N3 units derived from L-histidine that were
connected by a short, rigid ethanediamine bridge. In mXHI
the bridge is provided by the more extended m-xylyl moiety. The dicopper(II) complex [Cu2(mXHI)]4+ was studied as a
catalyst for stereoselective oxidations of enantiomeric couples of chiral catechols of biological interest (L/D-dopa, L/D-dopa
methyl ester, and (R/S)-norepinephrine), showing excellent discrimination capability, particularly for the methyl esters of dopa
enantiomers. The catechol oxidation was studied in acetate buffer as slightly acidic medium, and a role of acetate as bridging
ligand between the two coppers, preorganizing the dinuclear center in a more catalytic efficient structure, could be established.
The oxidation of β-naphthol and 3,5-ditertbutylphenol was studied as a model monophenolase reaction. The oxidation proceeds
stoichiometrically, and the partial incorporation of 18O into β-naphthol when the reaction was performed using 18O2 suggests
the existence of two competitive reaction pathways, a genuine monooxygenase mechanism and a radical pathway. However, the
more challenging reaction on derivatives of L-/D-tyrosine did not lead to the desired monooxygenase product but only to
products of radical oxidation. Complex [Cu2(mXHI)]4+ was also used for the catalytic sulfoxidation of thioanisole in the
presence of hydroxylamine as cosubstrate, in a preliminary attempt to model the reaction of external monooxygenases. The
reaction proceeds with 25 turnovers, but the enantiomeric excess of sulfoxide was modest.
Tipologia CRIS:
1.1 Articolo in rivista
Elenco autori:
Presti, E. L.; Perrone, M. L.; Santagostini, L.; Casella, L.; Monzani, E.
Link alla scheda completa:
Pubblicato in: