Physiology, biochemistry, and specific inhibitors of CH4, NH4+, and CO oxidation by methanotrophs and nitrifiers.

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Microbiol Mol Biol Rev. 1989 March; 53(1): 68-84

Physiology, biochemistry, and specific inhibitors of CH4, NH4+, and CO oxidation by methanotrophs and nitrifiers.

C Bédard and R Knowles

SUMMARY

Ammonia oxidizers (family Nitrobacteraceae) and methanotrophs(family Methylococcaceae) oxidize CO and CH4 to CO2 and NH4+to NO2-. However, the relative contributions of the two groupsof organisms to the metabolism of CO, CH4, and NH4+ in variousenvironments are not known. In the ammonia oxidizers, ammoniamonooxygenase, the enzyme responsible for the conversion ofNH4+ to NH2OH, also catalyzes the oxidation of CH4 to CH3OH.Ammonia monooxygenase also mediates the transformation of CH3OHto CO2 and cell carbon, but the pathway by which this is doneis not known. At least one species of ammonia oxidizer, Nitrosococcusoceanus, exhibits a Km for CH4 oxidation similar to that ofmethanotrophs. However, the highest rate of CH4 oxidation recordedin an ammonia oxidizer is still five times lower than ratesin methanotrophs, and ammonia oxidizers are apparently unableto grow on CH4. Methanotrophs oxidize NH4+ to NH2OH via methanemonooxygenase and NH4+ to NH2OH via methane monooxygenase andNH2OH to NO2- via an NH2OH oxidase which may resemble the enzymefound in ammonia oxidizers. Maximum rates of NH4+ oxidationare considerably lower than in ammonia oxidizers, and the affinityfor NH4+ is generally lower than in ammonia oxidizers. NH4+does not apparently support growth in methanotrophs. Both ammoniamonooxygenase and methane monooxygenase oxidize CO to CO2, butCO cannot support growth in either ammonia oxidizers or methanotrophs.These organisms have affinities for CO which are comparableto those for their growth substrates and often higher than thosein carboxydobacteria. The methane monooxygenases of methanotrophsexist in two forms: a soluble form and a particulate form. Thesoluble form is well characterized and appears unrelated tothe particulate. Ammonia monooxygenase and the particulate methanemonooxygenase share a number of similarities. Both enzymes containcopper and are membrane bound. They oxidize a variety of inorganicand organic compounds, and their inhibitor profiles are similar.Inhibitors thought to be specific to ammonia oxidizers havebeen used in environmental studies of nitrification. However,almost all of the numerous compounds found to inhibit ammoniaoxidizers also inhibit methanotrophs, and most of the inhibitorsact upon the monooxygenases. Many probably exert their effectby chelating copper, which is essential to the proper functioningof some monooxygenases. The lack of inhibitors specific forone or the other of the two groups of bacteria hampers the determinationof their relative roles in nature.

Microbiol Mol Biol Rev. 1989 March; 53(1): 68-84

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