mesna and propylene

Coenzyme M (2-mercaptoethanesulfonate; CoM) is one of several atypical cofactors discovered in methanogenic archaea which participate in the biological reduction of CO(2) to methane. Elegantly simple, CoM, so named for its role as a methyl carrier in all methanogenic archaea, is the smallest known organic cofactor. It was thought that this cofactor was used exclusively in methanogenesis until it was recently discovered that CoM is a key cofactor in the pathway of propylene metabolism in the gram-negative soil microorganism Xanthobacter autotrophicus Py2. A four-step pathway requiring CoM converts propylene and CO(2) to acetoacetate, which feeds into central metabolism. In this process, CoM is used to activate and convert highly electrophilic epoxypropane, formed from propylene epoxidation, into a nucleophilic species that undergoes carboxylation. The unique properties of CoM provide a chemical handle for orienting compounds for site-specific redox chemistry and stereospecific catalysis. The three-dimensional structures of several of the enzymes in the pathway of propylene metabolism in defined states have been determined, providing significant insights into both the enzyme mechanisms and the role of CoM in this pathway. These studies provide the structural basis for understanding the efficacy of CoM as a handle to direct organic substrate transformations at the active sites of enzymes.

Topics: Alkenes; Amino Acid Sequence; Mesna; Models, Molecular; Molecular Sequence Data; Structure-Activity Relationship; Xanthobacter

Coenzyme M (CoM, 2-mercaptoethanesulfonate), once thought to be exclusively produced by methanogens, is now known to be the central cofactor in the metabolism of short-chain alkenes by a variety of aerobic bacteria. There is little evidence to suggest how, and under what conditions, CoM is biosynthesized by these organisms. A shotgun proteomics approach was used to investigate CoM-dependent propylene metabolism in the Gram-negative bacterium Xanthobacter autotrophicus Py2. Cells were grown on either glucose or propylene, and the soluble proteomes were analyzed. An average of 395 proteins was identified from glucose-grown replicates, with an average of 419 identified from propylene-grown replicates. A number of linear megaplasmid (pXAUT01)-encoded proteins were found to be specifically produced by growth on propylene. These included all known to be crucial to propylene metabolism, in addition to an aldehyde dehydrogenase, a DNA-binding protein, and five putative CoM biosynthetic enzymes. This work has provided fresh insight into bacterial alkene metabolism and has generated new targets for future studies in X. autotrophicus Py2 and related CoM-dependent alkene-oxidizing bacteria.

Topics: Acetone; Alkenes; Culture Media; Epoxy Compounds; Glucose; Mesna; Oxygenases; Proteomics; Xanthobacter

Bacterial growth with short-chain aliphatic alkenes requires coenzyme M (CoM) (2-mercaptoethanesulfonic acid), which serves as the nucleophile for activation and conversion of epoxide products formed from alkene oxidation to central metabolites. In the present work the CoM analog 2-bromoethanesulfonate (BES) was shown to be a specific inhibitor of propylene-dependent growth of and epoxypropane metabolism by Xanthobacter autotrophicus strain Py2. BES (at low [millimolar] concentrations) completely prevented growth with propylene but had no effect on growth with acetone or n-propanol. Propylene consumption by cells was largely unaffected by the presence of BES, but epoxypropane accumulated in the medium in a time-dependent fashion with BES present. The addition of BES to cells resulted in time-dependent loss of epoxypropane degradation activity that was restored upon removal of BES and addition of CoM. Exposure of cells to BES resulted in a loss of epoxypropane-dependent CO(2) fixation activity that was restored only upon synthesis of new protein. Addition of BES to cell extracts resulted in an irreversible loss of epoxide carboxylase activity that was restored by addition of purified 2-ketopropyl-CoM carboxylase/oxidoreductase (2-KPCC), the terminal enzyme of epoxide carboxylation, but not by addition of epoxyalkane:CoM transferase or 2-hydroxypropyl-CoM dehydrogenase, the enzymes which catalyze the first two reactions of epoxide carboxylation. Comparative studies of the propylene-oxidizing actinomycete Rhodococcus rhodochrous strain B276 showed that BES is an inhibitor of propylene-dependent growth in this organism as well but is not an inhibitor of CoM-independent growth with propane. These results suggest that BES inhibits propylene-dependent growth and epoxide metabolism via irreversible inactivation of the key CO(2)-fixing enzyme 2-KPCC.

Topics: 1-Propanol; Acetone; Alkenes; Carbon Dioxide; Coenzymes; Epoxy Compounds; Ketone Oxidoreductases; Mesna; Oxidation-Reduction; Time Factors; Xanthobacter

Coenzyme M (CoM) (2-mercaptoethanesulfonic acid) biosynthesis is shown to be coordinately regulated with the expression of the enzymes of alkene and epoxide metabolism in the propylene-oxidizing bacteria Xanthobacter strain Py2 and Rhodococcus rhodochrous strain B276. These results provide the first evidence for the involvement of CoM in propylene metabolism by R. rhodochrous and demonstrate for the first time the inducible nature of eubacterial CoM biosynthesis.

Topics: Alkenes; Culture Media; Epoxy Compounds; Mesna; Oxygenases; Rhodococcus; Xanthobacter