Pyrazines are widespread chemical compounds that include pheromones and odors. Herein, a novel mechanism used by Pseudomonas fluorescens SBW25 to biosynthesize monocyclic pyrazines is reported. Heterologous expression of the papABC genes that synthesize the natural α‐amino acid 4‐aminophenylalanine (4APhe), together with three adjacent papDEF genes of unknown function, in Escherichia coli resulted in the production of 2,5‐dimethyl‐3,6‐bis(4‐aminobenzyl)pyrazine (DMBAP), which comprised two symmetrical aminobenzyl moieties derived from 4APhe. It is found that PapD is a novel amino acid C‐acetyltransferase, which decarboxylates and transfers acetyl residues to 4APhe, to generate an α‐aminoketone, which spontaneously dehydrates and condenses to give dihydro DMBAP. PapF is a novel oxidase in the amine oxidase superfamily that oxidizes dihydro DMBAP to yield the pyrazine ring of DMBAP. These two enzymes constitute a unique mechanism for synthesizing monocyclic pyrazines and might serve as a novel strategy for the enzymatic synthesis of pyrazine derivatives from natural α‐amino acids.
Sirtuin is an NAD-dependent histone deacetylase that is highly conserved among prokaryotes and eukaryotes. Sirtuin deacetylates histones and non-histone proteins, and it is involved in fungal growth and secondary metabolite production. Here, we screened 579 fungal culture extracts that inhibited the histone deacetylase activity of Sirtuin A (SirA), produced by the fungus Aspergillus nidulans. Eight fungal strains containing three Ascomycota, two Basidiomycota and three Deuteromycetes produced SirA inhibitors. We purified the SirA inhibitor from the culture broth of Didymobotryum rigidum JCM 8837, and identified it as 5-methylmellein-a known polyketide. This polyketide and its structurally-related compound, mellein, inhibited SirA activity with IC of 120 and 160 μM, respectively. Adding 5-methylmellein to A. nidulans cultures increased secondary metabolite production in the medium. The metabolite profiles were different from those obtained by adding other sirtuin inhibitors nicotinamide and sirtinol to the culture. These results indicated that 5-methylmellein modulates fungal secondary metabolism, and is a potential tool for screening novel compounds derived from fungi.
The actinobacterium splits riboflavin (vitamin B) into lumichrome and d-ribose. However, such degradation by other bacteria and the involvement of a two-component flavin-dependent monooxygenase (FMO) in the reaction remain unknown. Here we investigated the mechanism of riboflavin degradation by the riboflavin-assimilating alphaproteobacterium (formerly). We found that adding riboflavin to bacterial cultures induced riboflavin-degrading activity and a protein of the FMO family that had 67% amino acid identity with the predicted riboflavin hydrolase (RcaE) of MF109. The genome clustered genes encoding the predicted FMO, flavin reductase (FR), ribokinase, and flavokinase, and riboflavin induced their expression. This finding suggests that these genes constitute a mechanism for utilizing riboflavin as a carbon source. Recombinant FMO (rFMO) protein of oxidized riboflavin in the presence of reduced flavin mononucleotide (FMN) provided by recombinant FR (rFR), oxidized FMN and NADH, and produced stoichiometric amounts of lumichrome and d-ribose. Further investigation of the enzymatic properties of rFMO indicated that rFMO-rFR coupling accompanied O consumption and the generation of enzyme-bound hydroperoxy-FMN, which are characteristic of two-component FMOs. These results suggest that FMO is involved in hydroperoxy-FMN-dependent mechanisms to oxygenize riboflavin and a riboflavin monooxygenase is necessary for the initial step of riboflavin degradation. Whether bacteria utilize either a monooxygenase or a hydrolase for riboflavin degradation has remained obscure. The present study found that a novel riboflavin monooxygenase, not riboflavin hydrolase, facilitated this process in The riboflavin monooxygenase gene was clustered with flavin reductase, flavokinase, and ribokinase genes, and riboflavin induced their expression and riboflavin-degrading activity. The gene cluster is uniquely distributed in species and actinobacteria, which have exploited an environmental niche by developing adaptive mechanisms for riboflavin utilization.
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