2009 journal article

Metabolism and Cometabolism of Cyclic Ethers by a Filamentous Fungus, a Graphium sp.

APPLIED AND ENVIRONMENTAL MICROBIOLOGY, 75(17), 5514–5522.

By: K. Skinner*, L. Cuiffetti* & M. Hyman n 

co-author countries: United States of America πŸ‡ΊπŸ‡Έ
MeSH headings : 4-Butyrolactone / metabolism; Ascomycota / growth & development; Ascomycota / metabolism; Dioxanes / metabolism; Ethers, Cyclic / metabolism; Formaldehyde / metabolism; Formic Acid Esters / metabolism; Furans / metabolism; Metabolic Networks and Pathways; Methanol / metabolism; Models, Biological; Mycelium / growth & development; Mycelium / metabolism; Propane / metabolism
Source: Web Of Science
Added: August 6, 2018

The filamentous fungus Graphium sp. (ATCC 58400) grows on gaseous n-alkanes and diethyl ether. n-Alkane-grown mycelia of this strain also cometabolically oxidize the gasoline oxygenate methyl tert-butyl ether (MTBE). In this study, we characterized the ability of this fungus to metabolize and cometabolize a range of cyclic ethers, including tetrahydrofuran (THF) and 1,4-dioxane (14D). This strain grew on THF and other cyclic ethers, including tetrahydropyran and hexamethylene oxide. However, more vigorous growth was consistently observed on the lactones and terminal diols potentially derived from these ethers. Unlike the case in all previous studies of microbial THF oxidation, a metabolite, gamma-butyrolactone, was observed during growth of this fungus on THF. Growth on THF was inhibited by the same n-alkenes and n-alkynes that inhibit growth of this fungus on n-alkanes, while growth on gamma-butyrolactone or succinate was unaffected by these inhibitors. Propane and THF also behaved as mutually competitive substrates, and propane-grown mycelia immediately oxidized THF, without a lag phase. Mycelia grown on propane or THF exhibited comparable high levels of hemiacetal-oxidizing activity that generated methyl formate from mixtures of formaldehyde and methanol. Collectively, these observations suggest that THF and n-alkanes may initially be oxidized by the same monooxygenase and that further transformation of THF-derived metabolites involves the activity of one or more alcohol dehydrogenases. Both propane- and THF-grown mycelia also slowly cometabolically oxidized 14D, although unlike THF oxidation, this reaction was not sustainable. Specific rates of THF, 14D, and MTBE degradation were very similar in THF- and propane-grown mycelia.