Abstract
Cupric tyrosyl intermediates have been invoked as active oxidants in oxidase and oxygenase Cu-dependent metalloenzymes. Inspired by these natural oxidants, we report the proton-coupled electron transfer (PCET) reactivity of Cu complexes bound by a tridentate redox-active ONO pincer ligand and an ancillary amine ligand, [LCu(A)] (n+) (L = bis(3,5-di-tert-butyl-2-hydroxyphenyl)amine; A = triethylamine (NEt(3)) or N,N,N',N'-tetramethylpropane-1,3-diamine (tmpda); n = 0, 1). Analysis of the stoichiometry of the reactions indicated that the iminosemiquinone complex [(sq)LCu(NEt(3))] acts as 1H(+)/1e(-) PCET acceptor, while the benzoquinone analogue [(bq)LCu(NEt(3))](+) reacts in a 2H(+)/2e(-) fashion. Thermochemical analysis of the PCET reactivity of [(sq)LCu(NEt(3))] and [(bq)LCu(NEt(3))](+) revealed that [(bq)LCu(NEt(3))](+) is a stronger H-atom acceptor, which led to faster PCET reactions. [(bq)LCu(NEt(3))](+) reacted with substrates containing weak O-H bonds and, to our surprise, also abstracted H-atoms from C-H substrates. The reactivity of [(bq)LCu(NEt(3))](+) was compared with other Cu complexes developed in our laboratory that are stronger H-atom acceptors but do not oxidize C-H substrates, suggesting that non-thermodynamic factors contribute to the enhanced reactivity of [(bq)LCu(NEt(3))](+) towards C-H bonds. This work describes the first example of Cu complex bound by a redox-active ligand able to oxidize C-H bonds, and provides evidence of the involvement of similar species in the oxidation of organic substrates catalyzed by Cu-dependent metalloenzymes such as lytic polysaccharide monooxygenases.