O2 Reduction to Water by High Potential
Multicopper Oxidases: Contributions of the T1 Copper Site Potential
and the Local Environment of the Trinuclear Copper Cluster
posted on 2019-06-19, 00:00authored byAlina Sekretaryova, Stephen M. Jones, Edward I. Solomon
High
potential multicopper oxidases (MCOs) have T1 reduction potentials
>600 mV (vs normal hydrogen electrode), making them important catalysts
for O2 reduction in various biotechnological applications.
The oxygen reduction mechanism for the low potential MCOs is well-characterized;
however, O2 reactivity of high potential MCOs is not well
understood. In this study, we have shown that laccase from Trametes versicolor, where the T1 redox potential
is increased by ∼350 mV over that of the low potential MCOs
corresponding to an 8 kcal/mol decrease in the driving force, exhibits
a slower intramolecular electron transfer (IET) rate to the trinuclear
Cu cluster (TNC) in the native intermediate (NI), relative to the
low potential MCO from Rhus vernicifera laccase. This IET rate is, however, >102 times faster
than the decay rate of the NI, demonstrating that this intermediate
form of the enzyme is catalytically relevant enabling fast turnover.
However, in contrast to the low potential MCOs where T1 reduction
by substrate is rate limiting, the rate limiting step in turnover
of high potential MCOs is the first IET to NI. Part of the reduction
potential difference of the T1 sites in high vs low potential MCOs
is balanced by an ∼100 mV higher reduction potential of NI
due to the more positive protein environment in the vicinity of the
TNC.