热带念珠菌的木糖醇生物生产:葡萄糖/木糖比率和 pH 值对发酵和基因表达的影响。

IF 2.1 4区 生物学 Q3 MICROBIOLOGY
Sarah S Queiroz, Isabela S Campos, Tatiane F Silva, Maria das Graças A Felipe
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引用次数: 0

摘要

木糖醇是食品、制药和化工行业需求量很大的多元醇。然而,木糖醇目前的生产方法被认为是能源密集型的,需要使用有害的化学催化剂,并依赖于复杂而昂贵的设备。木糖醇生产的生物技术路线被认为是一种可持续的替代方法,但仍需要改进工艺,如提高发酵能力,才能具有经济竞争力。本研究考察了热带念珠菌酵母通过葡萄糖:木糖比例和 pH 值调节来提高木糖到木糖醇的转化率。评估的主要参数包括木糖消耗率(rS)、木糖-木糖醇产量(YP/S)和木糖醇体积生产率(QP)。在 pH 值为 3.5、木糖含量为 50 克/升的条件下,木糖醇产量较高:48 小时时,木糖醇产量为 29.81 克/升,QP 为 0.52 克/升/小时,YP/S 为 0.54 克/克。这为通过酵母基因工程方法进行探索提供了机会。此外,在所有测试条件下,对之前在热带酵母中发现的木糖转运体基因(XUT1 和 STL2)和木糖还原酶基因(XYL1)的定量表达进行了评估。XUT1 的上调与木糖浓度较高有关,而 STL2 则在木糖浓度较低时更易上调。XYL1 的表达随木糖比率升高而上调。高转录水平和表达特征表明,Xut1p 介导的木糖转运是通过质子交感机制进行的。结果表明,pH因子间接影响了XUT1基因的转录,这可能是对高pH条件下转运效率降低的一种补偿反应。本研究强调了葡萄糖比率和 pH 值对木糖醇生产的影响,以及木糖转运体和关键酶木糖还原酶基因表达的影响。利用这些见解可以通过生物技术途径显著提高半纤维素水解物的木糖醇产量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Xylitol bioproduction by Candida tropicalis: effects of glucose/xylose ratio and pH on fermentation and gene expression.

Xylitol is a highly demanded polyol in the food, pharmaceutical, and chemical industries. However, its current production methods are considered energy-intensive, require the use of hazardous chemical catalysts, and depend on complex and costly equipment. The biotechnological route of xylitol production is proposed as a sustainable alternative, but it still requires process improvements, such as enhanced fermentation capabilities, to be economically competitive. This study examined Candida tropicalis yeast to improve xylose-to-xylitol conversion via glucose: xylose ratio and pH modulation. Key parameters evaluated included xylose consumption rate (rS), xylose-to-xylitol yield (YP/S), and xylitol volumetric productivity (QP). Conditions with 50 g/L xylose at pH 3.5 exhibited superior xylitol production: 29.81 g/L, QP of 0.52 g/L/h, and YP/S of 0.54 g/g at 48 h. The statistical model demonstrated that the maximum YP/S and QP values have not yet been achieved. This could present an opportunity to be explored through yeast genetic engineering approaches. Additionally, the quantitative expression of the xylose transporter genes (XUT1 and STL2) and the xylose reductase gene (XYL1), previously identified in C. tropicalis, was evaluated under all tested conditions. Upregulation of the XUT1 was correlated with higher xylose concentrations, while STL2 was favored at lower xylose concentrations. The expression of XYL1 showed upregulation over time with higher xylose ratios. The high transcription levels and expression profile suggest that Xut1p-mediated xylose transport occurs through a proton symport mechanism. The results indicate that the pH factor indirectly influences XUT1 gene transcription, possibly as a compensatory response to the reduced transporter efficiency under high pH conditions. The present work underscores the influence of glucose ratios and pH in xylitol production, as well as the gene expression of xylose transporters and the key enzyme xylose reductase. Leveraging these insights can significantly enhance xylitol production from hemicellulosic hydrolysates through biotechnological pathways.

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来源期刊
Brazilian Journal of Microbiology
Brazilian Journal of Microbiology 生物-微生物学
CiteScore
4.10
自引率
4.50%
发文量
216
审稿时长
1.0 months
期刊介绍: The Brazilian Journal of Microbiology is an international peer reviewed journal that covers a wide-range of research on fundamental and applied aspects of microbiology. The journal considers for publication original research articles, short communications, reviews, and letters to the editor, that may be submitted to the following sections: Biotechnology and Industrial Microbiology, Food Microbiology, Bacterial and Fungal Pathogenesis, Clinical Microbiology, Environmental Microbiology, Veterinary Microbiology, Fungal and Bacterial Physiology, Bacterial, Fungal and Virus Molecular Biology, Education in Microbiology. For more details on each section, please check out the instructions for authors. The journal is the official publication of the Brazilian Society of Microbiology and currently publishes 4 issues per year.
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