Optimized Feeding Strategies for Biosurfactant Production from Acetate by Alcanivorax borkumensis SK2

T. Karmainski, M. K. Lipa, Sonja Kubicki, Amina Bouchenafa, S. Thies, Karl-Erich Jaeger, Lars M. Blank, T. Tiso
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Abstract

Biosurfactants are much-discussed alternatives to petro- and oleochemical surfactants. Alcanivorax borkumensis, a marine, Gram-negative γ-proteobacterium, produces a glycine-glucolipid biosurfactant from hydrocarbons, pyruvate, and acetate as carbon sources. Sustainable acetate production from lignocellulose or syngas adds to its relevance for the bioeconomy. This study investigated nitrogen sources and carbon-to-nitrogen ratios (C/N) to optimize fed-batch fermentation for biosurfactant production using A. borkumensis with acetate as the carbon source. Urea enabled high biosurfactant production, which was confirmed in DO-based fed-batch fermentation. Varying C/N ratios led to increased glycine-glucolipid production and decreased biomass production, with improvement plateauing at a C/N ratio of 26.7 Cmol Nmol−1. pH-stat fed-batch fermentation using glacial acetic acid as the carbon source and a pH-adjusting agent doubled the biosurfactant production. Finally, bubble-free membrane aeration was used to prevent extensive foam formation observed during conventional bubble aeration. The efficient production made it possible to investigate the bioactivity of glycine-glucolipid in combination with antibiotics against various microorganisms. Our findings allow for the leverage of glycine-glucolipid biosurfactant production using acetate as a carbon source.
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优化喂食策略,促进 Alcanivorax borkumensis SK2 利用醋酸生产生物表面活性剂
生物表面活性剂是备受讨论的石油和油化学表面活性剂的替代品。Alcanivorax borkumensis 是一种海洋革兰氏阴性 γ 蛋白细菌,它以碳氢化合物、丙酮酸和醋酸盐为碳源,生产出一种甘氨酸-葡萄糖脂生物表面活性剂。以木质纤维素或合成气为原料生产可持续的醋酸盐,使其在生物经济中的作用更加重要。本研究调查了氮源和碳氮比(C/N),以优化以乙酸盐为碳源的 A. borkumensis 的饲料批量发酵生物表面活性剂生产。尿素能够提高生物表面活性剂的产量,这一点在基于溶解氧的饲料批量发酵中得到了证实。不同的 C/N 比会导致甘氨酸-葡糖脂产量的增加和生物量产量的减少,当 C/N 比为 26.7 Cmol Nmol-1 时,生物量产量的提高趋于稳定。使用冰醋酸作为碳源和 pH 值调节剂进行 pH 值恒定饲料批量发酵,生物表面活性剂的产量增加了一倍。最后,采用了无气泡膜通气技术,以防止在传统气泡通气过程中产生大量泡沫。高效的生产使得研究甘氨酸-葡糖脂与抗生素结合对各种微生物的生物活性成为可能。我们的研究结果有助于利用醋酸盐作为碳源生产甘氨酸-葡糖脂生物表面活性剂。
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