Aachener Verfahrenstechnik - Process Systems Engineering (AVT.SVT), RWTH Aachen University, Aachen, Germany.
Institute of Applied Microbiology (iAMB), Aachen Biology and Biotechnology (ABBt), RWTH Aachen University, Aachen, Germany.
Biotechnol Bioeng. 2024 Jun;121(6):1846-1858. doi: 10.1002/bit.28693. Epub 2024 Mar 17.
Itaconic acid is a platform chemical with a range of applications in polymer synthesis and is also discussed for biofuel production. While produced in industry from glucose or sucrose, co-feeding of glucose and acetate was recently discussed to increase itaconic acid production by the smut fungus Ustilago maydis. In this study, we investigate the optimal co-feeding conditions by interlocking experimental and computational methods. Flux balance analysis indicates that acetate improves the itaconic acid yield up to a share of 40% acetate on a carbon molar basis. A design of experiment results in the maximum yield of 0.14 itaconic acid per carbon source from 100 glucose and 12 acetate. The yield is improved by around 22% when compared to feeding of glucose as sole carbon source. To further improve the yield, gene deletion targets are discussed that were identified using the metabolic optimization tool OptKnock. The study contributes ideas to reduce land use for biotechnology by incorporating acetate as co-substrate, a C2-carbon source that is potentially derived from carbon dioxide.
衣康酸是一种平台化学品,在聚合物合成中有广泛的应用,也被讨论用于生物燃料生产。虽然工业上是从葡萄糖或蔗糖中生产的,但最近有研究讨论了共喂食葡萄糖和醋酸盐来增加黑粉菌(Ustilago maydis)的衣康酸产量。在这项研究中,我们通过实验和计算方法的相互结合来研究最佳的共喂食条件。通量平衡分析表明,醋酸盐可以将衣康酸的产量提高到基于碳摩尔的 40%醋酸盐的比例。实验设计的结果是,从 100 克葡萄糖和 12 克醋酸盐中,每碳源可获得 0.14 克衣康酸的最大产量。与仅以葡萄糖作为碳源相比,产量提高了约 22%。为了进一步提高产量,我们使用代谢优化工具 OptKnock 讨论了基因缺失靶点。该研究通过引入醋酸盐作为共底物的想法为减少生物技术的土地使用做出了贡献,醋酸盐是一种潜在的来源于二氧化碳的 C2 碳源。
