e characterization of pMMO and sMMO, and acquisition and handlin

e. characterization of pMMO and sMMO, and acquisition and handling of copper by methanobactin. However, the recent findings of the large complement of c-type cytochromes in

M. capsulatus Bath, their unusual cellular surface localization, and copper-dependent expression and their putative roles in the copper homeostasis and metabolic flexibility, post-translational modifications (exemplified by the formation of kynurenine in MopE), open new fields of research on this model methanotroph. Importantly, searches for surface exposed c-type cytochromes in a broader range of methanotrophic bacteria may aid addressing these emerging questions. For example, is such redox active CX-4945 surface enzymes important for cells to survive in methanotrophic communities distributed in several different redox conditions? Is the presence of such enzymes in methanotrophs linked to the bioavailability of copper, due to the likely limiting copper availability at lower redox conditions which may result in insoluble copper complexes? It has also been shown that c-type cytochromes are involved in the siderophore biosynthesis in other

bacteria (Yip et al., 2011), and it is at present an open question if such enzymes are involved in the maturation of methanobactin in M. capsulatus Bath. Furthermore, several protein families and proteins (e.g. cytochrome c553o family proteins, ‘MCA0445’, ‘MCA0446’ and ‘MCA0347’ and others) still appear to be unique to this bacterium and of unknown function. Importantly, several of these findings indicate a hitherto unrecognized plasticity of the metabolic pathways in M. capsulatus Bath. This plasticity may be essential to the bacterium to efficiently Selleckchem MK-8669 adapt to a wide variety in copper conditions. In our opinion, many of these observations warrant further research, and have the potential to reveal unanticipated properties important to fully understand the biology and potentials of methanotrophy. This work was supported by the Norwegian Research Council (grant no. 101742). We would like to acknowledge Professor

Johan Lillehaug at the University of Bergen for interesting and useful discussions. “
“Methanotrophs (-)-p-Bromotetramisole Oxalate are a group of phylogenetically diverse microorganisms characterized by their ability to utilize methane as their sole source of carbon and energy. Early studies suggested that growth on methane could be stimulated with the addition of some small organic acids, but initial efforts to find facultative methanotrophs, i.e., methanotrophs able to utilize compounds with carbon–carbon bonds as sole growth substrates were inconclusive. Recently, however, facultative methanotrophs in the genera Methylocella, Methylocapsa, and Methylocystis have been reported that can grow on acetate, as well as on larger organic acids or ethanol for some species. All identified facultative methanotrophs group within the Alphaproteobacteria and utilize the serine cycle for carbon assimilation from formaldehyde.

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