Multi-Energy Metabolic Mechanisms of the Fungus Fusarium oxysporum in Low Oxygen Environments
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概要
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The fungus Fusarium oxysporum produces energy under hypoxic and anoxic conditions by denitrification (nitrate respiration) and ammonia fermentation respectively. Here we found that glucose repressed both of these metabolisms, whereas it supported another anoxic metabolism, hetero-lactic acid fermentation. Ammonia fermentation occurred only after the glucose present in the medium was metabolized to ethanol via alcohol fermentation. During this transition, clear diauxic growth was observed. Glucose regulated the activity of the enzymes involved in ammonia fermentation, hetero-lactic acid fermentation, and denitrification. Highest cell growth was supported by hetero-lactic acid fermentation, followed by denitrification and ammonia fermentation. These results indicate that the energy metabolisms of F. oxysporum are dependent not only on environmental O2 tension but also on the carbon source, and that ammonia fermentation is an adaptative mechanism acting physiologically as a secondary fermentative mechanism replacing the primary hetero-lactic acid fermentation.
- 社団法人 日本農芸化学会の論文
- 2010-12-23
著者
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Shoun Hirofumi
Department Of Biotechnology Graduate School Of Agricultural And Life Sciences The University Of Toky
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Shoun Hirofumi
Department Of Agricultural Chemistry The University Of Tokyo:(present Office)institute Of Applied Bi
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Takaya Naoki
Graduate School Of Life And Environmental Sciences Univ. Of Tsukuba
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Zhou Zhemin
The Key Laboratory Of Industrial Biotechnology Ministry Of Education School Of Biotechnology Jiangna
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