厌氧真菌Neocallimastix cameroonii G341黑暗发酵过程中向增加生物产氢的代谢转变。

Marcus Stabel, Karoline Haack, Hannah Lübbert, Meike Greif, Pascal Gorenflo, Habibu Aliyu, Katrin Ochsenreither
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引用次数: 1

摘要

背景:Neocallimastigomycota门厌氧真菌由于其强大的木质纤维素降解能力和几种有价值的代谢物如氢、乙酸、甲酸、乳酸和乙醇的生产,具有很高的生物技术潜力。然而,由于目前在静止瓶中的培养策略的限制,这些真菌的代谢仍然知之甚少,从而限制了培养条件的综合评价。结果:我们描述了先前分离的真菌Neocallimastix cameroonii G341的生长条件及其对代谢的影响。我们在搅拌槽中建立了生物反应器过程,使其能够在规定的条件下进行培养。真菌的最适生长温度为38.5 ~ 41.5℃,最适pH为6.6 ~ 6.8。与其他暗发酵系统一样,氢气的产生取决于氢气的分压和ph值。摇动瓶子或搅拌发酵罐会导致氢气的增加,而乳酸盐和乙醇的产生则会减少。将发酵罐的pH值调节到6.8,产生的氢气量几乎翻了一番。结论:对Neocallimastix cameroonii的代谢有了新的认识,氢是比乳酸和乙醇更好的电子处理方式。此外,我们的研究强调了真菌在未经预处理的生物质制氢方面的潜在应用。最后,我们在搅拌槽反应器系统中建立了厌氧真菌的第一次培养。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Metabolic shift towards increased biohydrogen production during dark fermentation in the anaerobic fungus Neocallimastix cameroonii G341.

Metabolic shift towards increased biohydrogen production during dark fermentation in the anaerobic fungus Neocallimastix cameroonii G341.

Metabolic shift towards increased biohydrogen production during dark fermentation in the anaerobic fungus Neocallimastix cameroonii G341.

Metabolic shift towards increased biohydrogen production during dark fermentation in the anaerobic fungus Neocallimastix cameroonii G341.

Background: Anaerobic fungi of the phylum Neocallimastigomycota have a high biotechnological potential due to their robust lignocellulose degrading capabilities and the production of several valuable metabolites like hydrogen, acetate, formate, lactate, and ethanol. The metabolism of these fungi, however, remains poorly understood due to limitations of the current cultivation strategies in still-standing bottles, thereby restricting the comprehensive evaluation of cultivation conditions.

Results: We describe the analysis of growth conditions and their influence on the metabolism of the previously isolated fungus Neocallimastix cameroonii G341. We established a bioreactor process in a stirred tank, enabling cultivation under defined conditions. The optimal growth temperature for the fungus was between 38.5 °C and 41.5 °C, while the optimal pH was 6.6-6.8. Like other dark fermentation systems, hydrogen production is dependent on the hydrogen partial pressure and pH. Shaking the bottles or stirring the fermenters led to an increase in hydrogen and a decrease in lactate and ethanol production. Regulation of the pH to 6.8 in the fermenter nearly doubled the amount of produced hydrogen.

Conclusions: Novel insights into the metabolism of Neocallimastix cameroonii were gained, with hydrogen being the preferred way of electron disposal over lactate and ethanol. In addition, our study highlights the potential application of the fungus for hydrogen production from un-pretreated biomass. Finally, we established the first cultivation of an anaerobic fungus in a stirred tank reactor system.

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