Identifying the chloroperoxyl radical in acidified sodium chlorite solution.

The present study identified the active radical species in acidic sodium chlorite and investigated the feasibility of quantifying these species with the diethylphenylenediamine (DPD) method. Electron spin resonance (ESR) spectroscopy was used to identify the active species generated in solutions containing sodium chlorite (NaClO2). The ESR signal was directly observed in an acidified sodium chlorite (ASC) aqueous solution at room temperature. This ESR signal was very long-lived, indicating that the radical was thermodynamically stable. The ESR parameters of this signal did not coincide with previously reported values of the chlorine radical (Cl●) or chlorine dioxide radical (O = Cl●-O and O = Cl-O●). We refer to this signal as being from the chloroperoxyl radical (Cl-O-O●). Quantum chemical calculations revealed that the optimal structure of the chloroperoxyl radical is much more thermodynamically stable than that of the chlorine dioxide radical. The UV-visible spectrum of the chloroperoxyl radical showed maximum absorbance at 354 nm. This absorbance had a linear relationship with the chloroperoxyl radical ESR signal intensity. Quantifying the free chlorine concentration by the DPD method also revealed a linear relationship with the maximum absorbance at 354 nm, which in turn showed a linear relationship with the chloroperoxyl radical ESR signal intensity. These linear relationships suggest that the DPD method can quantify chloroperoxyl radicals, which this study considers to be the active species in ASC aqueous solution.

Switching Between Methanol Accumulation and Cell Growth by Expression Control of Methanol Dehydrogenase in Methylosinus trichosporium OB3b Mutant.

Methanotrophs have been used to convert methane to methanol at ambient temperature and pressure. In order to accumulate methanol using methanotrophs, methanol dehydrogenase (MDH) must be downregulated as it consumes methanol. Here, we describe a methanol production system wherein MDH expression is controlled by using methanotroph mutants. We used the MxaF knockout mutant of Methylosinus trichosporium OB3b. It could only grow with MDH (XoxF) which has a cerium ion in its active site and is only expressed by bacteria in media containing cerium ions. In the presence of 0 µM copper ion and 25 µM cerium ion, the mutant grew normally. Under conditions conducive to methanol production (10 µM copper ion and 0 µM cerium ion), cell growth was inhibited and methanol accumulated (2.6 µmol·mg-1 dry cell weight·h-1). The conversion efficiency of the accumulated methanol to the total amount of methane added to the reaction system was ~0.3%. The aforementioned conditions were repeatedly alternated by modulating the metal ion composition of the bacterial growth medium.

Methane Hydroxylation with Water as an Electron Donor under Light Irradiation in the Presence of Reconstituted Membranes Containing both Photosystem†II and a Methane Monooxygenase.

Methane/methanol conversion is one of the most important chemical reactions. Methane monooxygenases from methanotrophs are enzymes that catalyze methane/methanol conversion under mild conditions. Here we report the reconstitution of purified photosystem II (PSII) from Thermosynechococcus elongatus BP-1 into the membrane fraction containing particulate methane monooxygenase (pMMO) from Methylosinus trichosporium OB3b. Photoinduced hydroxylation of methane to methanol was successfully achieved by using the PSII-reconstituted membrane containing pMMO under light irradiation. This result indicates that the sequential redox chain from PSII through the quinone pool to pMMO can be constructed and that water can serve as the electron donor for methane hydroxylation under irradiation with light. pMMO in the membrane fraction produced hydrogen peroxide as a byproduct when an electron donor was added for methane hydroxylation, whereas under light irradiation conditions the PSII-reconstituted membrane containing pMMO did not generate hydrogen peroxide. Optimization of the electron-transfer rate can easily be achieved with this system by tuning the light intensity.