PhoP may serve to integrate the lipid signalling system into the cellular network of regulatory circuits in P. aeruginosa. The elucidation of the physiological functions of lipolytic enzymes may therefore help to develop novel
therapeutic concepts against P. aeruginosa infections. We thank Søren Molin (Danish Technical University, Lyngby, Denmark) and his coworkers for hosting D.T. and also for their great help with biofilm analysis. “
“The gene clusters encoding soluble methane monooxygenase (sMMO) and particulate methane monooxygenase (pMMO) were cloned and sequenced from a new type I methanotroph, Methylovulum miyakonense HT12. The sMMO gene cluster consisted of the structural genes mmoXYBZDC, the regulatory genes mmoG and mmoR and another ORF orf1. Transcriptional analysis revealed that these sMMO genes were transcribed as a single unit from a σ54-dependent promoter located upstream EPZ015666 datasheet of click here mmoX. In the pMMO gene cluster, the pmoCAB operon was under the control of a σ70-dependent promoter. The organization
of each MMO operon was largely conserved with that of the previously described methanotrophs. However, unlike other methanotrophs, M. miyakonense HT12 harbored only a single copy of the pmoCAB gene. These data provide new insights into the structure of MMO genes. Methanotrophs capable of utilizing methane as a sole carbon and energy source are of great interest because of their ability to oxidize atmospheric methane, which is the second most effective greenhouse gas. The key enzyme in methane metabolism is methane monooxygenase (MMO), which catalyzes the oxidation of methane to methanol (Hanson & Hanson, 1996). There are two distinct types of MMO enzymes: a cytoplasmic soluble enzyme (sMMO) and a membrane-bound particulate enzyme (pMMO) (Semrau et al., 2010). pMMO is produced by all known methanotrophs (except for Methylocella), whereas sMMO is produced by several strains of methanotrophs. In cells that synthesize both types of enzyme, sMMO
is expressed at low copper–biomass ratios, while pMMO is expressed at high copper–biomass ratios. Methanotrophs within the Proteobacteria are divided into two major groups based on the phenotypic Buspirone HCl and genotypic properties (Hanson & Hanson, 1996). Type I methanotrophs and its subgroup type X methanotrophs (i.e. Methylococcus) include 12 genera, while type II methanotrophs include four genera (Semrau et al., 2010). In contrast to type II methanotrophs, little is known about the MMO genes and the regulatory machinery for gene expression in type I methanotrophs, except Methylococcus capsulatus Bath, which has been studied as a model methanotroph strain, but has some unusual physiological features that are not found in other type I methanotrophs (Hanson & Hanson, 1996).