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使用化学定义的合成水解产物进行多组学发酵揭示了木质纤维素衍生抑制剂对细胞生理学和木糖利用的多种影响。

Multiomic Fermentation Using Chemically Defined Synthetic Hydrolyzates Revealed Multiple Effects of Lignocellulose-Derived Inhibitors on Cell Physiology and Xylose Utilization in .

作者信息

Zhang Yaoping, Vera Jessica M, Xie Dan, Serate Jose, Pohlmann Edward, Russell Jason D, Hebert Alexander S, Coon Joshua J, Sato Trey K, Landick Robert

机构信息

DOE-Great Lakes Bioenergy Research Center, University of Wisconsin-Madison, Madison, WI, United States.

出版信息

Front Microbiol. 2019 Nov 7;10:2596. doi: 10.3389/fmicb.2019.02596. eCollection 2019.

DOI:10.3389/fmicb.2019.02596
PMID:31787963
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6853872/
Abstract

Utilization of both C5 and C6 sugars to produce biofuels and bioproducts is a key goal for the development of integrated lignocellulosic biorefineries. Previously we found that although engineered 2032 was able to ferment glucose to ethanol when fermenting highly concentrated hydrolyzates such as 9% glucan-loading AFEX-pretreated corn stover hydrolyzate (9% ACSH), xylose conversion after glucose depletion was greatly impaired. We hypothesized that impaired xylose conversion was caused by lignocellulose-derived inhibitors (LDIs) in hydrolyzates. To investigate the effects of LDIs on the cellular physiology of during fermentation of hydrolyzates, including impacts on xylose utilization, we generated synthetic hydrolyzates (SynHs) that contained nutrients and LDIs at concentrations found in 9% ACSH. Comparative fermentations of 2032 using SynH with or without LDIs were performed, and samples were collected for end product, transcriptomic, metabolomic, and proteomic analyses. Several LDI-specific effects were observed at various timepoints during fermentation including upregulation of sulfur assimilation and cysteine biosynthesis, upregulation of RND family efflux pump systems (ZMO0282-0285) and ZMO1429-1432, downregulation of a Type I secretion system (ZMO0252-0255), depletion of reduced glutathione, and intracellular accumulation of mannose-1P and mannose-6P. Furthermore, when grown in SynH containing LDIs, 2032 only metabolized ∼50% of xylose, compared to ∼80% in SynH without LDIs, recapitulating the poor xylose utilization observed in 9% ACSH. Our metabolomic data suggest that the overall flux of xylose metabolism is reduced in the presence of LDIs. However, the expression of most genes involved in glucose and xylose assimilation was not affected by LDIs, nor did we observe blocks in glucose and xylose metabolic pathways. Accumulations of intracellular xylitol and xylonic acid was observed in both SynH with and without LDIs, which decreased overall xylose-to-ethanol conversion efficiency. Our results suggest that xylose metabolism in 2032 may not be able to support the cellular demands of LDI mitigation and detoxification during fermentation of highly concentrated lignocellulosic hydrolyzates with elevated levels of LDIs. Together, our findings identify several cellular responses to LDIs and possible causes of impaired xylose conversion that will enable future strain engineering of

摘要

利用C5和C6糖类生产生物燃料和生物制品是综合木质纤维素生物精炼厂发展的关键目标。此前我们发现,尽管工程菌2032在发酵高浓度水解产物(如9%葡聚糖负载的AFEX预处理玉米秸秆水解产物,9% ACSH)时能够将葡萄糖发酵为乙醇,但葡萄糖耗尽后木糖转化率大幅受损。我们推测木糖转化率受损是由水解产物中木质纤维素衍生抑制剂(LDI)引起的。为了研究LDI在水解产物发酵过程中对细胞生理的影响,包括对木糖利用的影响,我们制备了含有9% ACSH中发现的营养物质和LDI浓度的合成水解产物(SynHs)。使用含或不含LDI的SynH对2032进行了比较发酵,并收集样品进行终产物分析、转录组学分析、代谢组学分析和蛋白质组学分析。在发酵的不同时间点观察到了几种LDI特异性效应,包括硫同化和半胱氨酸生物合成的上调、RND家族外排泵系统(ZMO0282 - 0285)和ZMO1429 - 1432的上调、I型分泌系统(ZMO0252 - 0255)的下调、还原型谷胱甘肽的消耗以及甘露糖-1P和甘露糖-6P的细胞内积累。此外,当在含有LDI的SynH中生长时,2032仅代谢了约50%的木糖,而在不含LDI的SynH中这一比例约为80%,这重现了在9% ACSH中观察到的木糖利用不佳的情况。我们的代谢组学数据表明,在存在LDI的情况下,木糖代谢的总体通量降低。然而,大多数参与葡萄糖和木糖同化的基因表达不受LDI影响,我们也未观察到葡萄糖和木糖代谢途径的阻断。在含和不含LDI的SynH中均观察到细胞内木糖醇和木糖酸的积累,这降低了木糖到乙醇的总体转化效率。我们的结果表明,在高浓度木质纤维素水解产物且LDI水平升高的发酵过程中,2032中的木糖代谢可能无法满足减轻LDI和解毒的细胞需求。总之,我们的研究结果确定了对LDI的几种细胞反应以及木糖转化受损的可能原因,这将为未来的菌株工程提供依据

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