Abstract
In this manuscript, we report that a bacterial multicopper oxidase (MCO266) catalyzes Mn(II) oxidation on the cell surface, resulting in the surface deposition of Mn(III) and Mn(IV) oxides and the gradual formation of bulky oxide aggregates. These aggregates serve as nucleation centers for the formation of Mn oxide micronodules and Mn-rich sediments. A soil-borne Escherichia coli with high Mn(II)-oxidizing activity formed Mn(III)/Mn(IV) oxide deposit layers and aggregates under laboratory culture conditions. We engineered MCO266 onto the cell surfaces of both an activity-negative recipient and wild-type strains. The results confirmed that MCO266 governs Mn(II) oxidation and initiates the formation of deposits and aggregates. By contrast, a cell-free substrate, heat-killed strains, and intracellularly expressed or purified MCO266 failed to catalyze Mn(II) oxidation. However, purified MCO266 exhibited Mn(II)-oxidizing activity when combined with cell outer membrane component (COMC) fractions in vitro. We demonstrated that Mn(II) oxidation and aggregate formation occurred through an oxygen-dependent biotic transformation process that requires a certain minimum Mn(II) concentration. We propose an approximate electron transfer pathway in which MCO266 transfers only one electron to convert Mn(II) to Mn(III) and then cooperates with other COMC electron transporters to transfer the other electron required to oxidize Mn(III) to Mn(IV).
Highlights
IntroductionA region rich in methionine near the T1 copper site that senses copper is required for the binding activity of the fifth copper[24,25,26]
This study demonstrates that MCO266 is an Mn(II)-oxidizing protein that actuates Mn oxide deposition onto the bacterial cell surface and successively forms oxide aggregates
Both wild-type E. coli MB266 and the recombinant E. coli strains with surface-displayed MCO266 are capable of producing microspherical aggregates of Mn oxides
Summary
A region rich in methionine near the T1 copper site that senses copper is required for the binding activity of the fifth copper[24,25,26] These MCO-mediated oxidation reactions all appear to be related to the cell surface; investigating the role of MCOs in Mn oxidation on the cell surface will improve the understanding of the biogenesis of Mn oxide minerals in the soil environment. The objective of the current study was to define the role of an MCO protein (MCO266) from a soil-borne Mn(II)-oxidizing bacterium in bacterial cell-surface-orientated Mn oxidation and the biomineralization of Mn oxides. For this purpose, an MCO heterologous expression system for Mn(II) oxidation was established using the surface-display system of E. coli. MCO266 is involved in the biological nucleation of Mn oxides under laboratory conditions
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