Katharina Oehlenschläger, Michaela Lorenz, Emily Schepp, Sarah Di Nonno, Dirk Holtmann, Roland Ulber
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The effects of varying inoculation times in co-culture were examined, considering the solvent and acid tolerance of both strains. Due to the limited acid tolerance of <i>S. cerevisiae</i>, with significant inhibition at butyric acid concentrations above 10 g L¯<sup>1</sup>, a time-delayed inoculation with <i>C. tyrobutyricum</i> was implemented. In batch experiments, the final concentrations of butyric acid and ethanol were 13.98 ± 3.06 g L¯<sup>1</sup> and 21.43 ± 1.66 g L¯<sup>1</sup>, respectively. Further enhancement of product concentrations was explored through a fed-batch cultivation strategy yielding up to 45.62 ± 3.82 g L¯<sup>1</sup> of butyric acid and 18.61 ± 4.11 g L¯<sup>1</sup> of ethanol. Ethyl butyrate was formed from the fermentation products by lipase-catalysed enzymatic esterification in a two-phase system through the addition of an organic phase. 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引用次数: 0
摘要
对天然产品不断增长的需求正在加速对生产丁酸乙酯等生物基香料的可持续方法的研究。本研究以酪氨酸丁酸梭菌和酿酒酵母共同培养的丁酸和乙醇为原料,通过酶促酯化法制备了丁酸乙酯。对两种菌株进行了初步的单培养实验,以研究共同培养的妥协发酵条件。在此基础上,建立了厌氧共培养条件,温度37℃,转速150 rpm, pH控制在6。考虑到两菌株的耐溶剂性和耐酸性,考察了不同接种次数对共培养的影响。由于酿酒酵母的耐酸能力有限,在丁酸浓度大于10 g L¯1时具有明显的抑制作用,因此采用延迟接种酪氨酸丁酸酵母的方法。在批量实验中,丁酸和乙醇的最终浓度分别为13.98±3.06 g L¯1和21.43±1.66 g L¯1。通过补料分批培养策略,进一步提高产品浓度,丁酸产量为45.62±3.82 g L¯1,乙醇产量为18.61±4.11 g L¯1。在两相体系中,通过添加有机相,由脂肪酶催化的酶促酯化反应生成丁酸乙酯。有机相的酯浓度最高可达23.93±0.68 g L¯1(酯化率25%)。本研究提出了一种可行的方法来生产生物基丁酸乙酯,为传统的化学合成方法提供了一种可持续的选择。
Integrated co-cultivation and subsequent esterification: Harnessing Saccharomyces cerevisiae and Clostridium tyrobutyricum for streamlined ester production
The rising demand for natural products is accelerating research into sustainable methods for producing bio-based flavourings like ethyl butyrate. In this study, ethyl butyrate was successfully produced through the enzymatic esterification of butyric acid and ethanol, which were derived from the co-cultivation of Clostridium tyrobutyricum and Saccharomyces cerevisiae. Initial monoculture experiments with both strains were performed to investigate compromised fermentation conditions for co-cultivation. Based on these findings, anaerobic co-cultivation conditions were established at 37 °C and 150 rpm, with the pH controlled at 6. The effects of varying inoculation times in co-culture were examined, considering the solvent and acid tolerance of both strains. Due to the limited acid tolerance of S. cerevisiae, with significant inhibition at butyric acid concentrations above 10 g L¯1, a time-delayed inoculation with C. tyrobutyricum was implemented. In batch experiments, the final concentrations of butyric acid and ethanol were 13.98 ± 3.06 g L¯1 and 21.43 ± 1.66 g L¯1, respectively. Further enhancement of product concentrations was explored through a fed-batch cultivation strategy yielding up to 45.62 ± 3.82 g L¯1 of butyric acid and 18.61 ± 4.11 g L¯1 of ethanol. Ethyl butyrate was formed from the fermentation products by lipase-catalysed enzymatic esterification in a two-phase system through the addition of an organic phase. The ester concentration in the organic phase reached a maximum of 23.93 ± 0.68 g L¯1 (esterification yield 25%). This study presents a viable approach to the production of bio-based ethyl butyrate offering a sustainable alternative to traditional chemical synthesis methods.
期刊介绍:
Biotechnology for Biofuels is an open access peer-reviewed journal featuring high-quality studies describing technological and operational advances in the production of biofuels, chemicals and other bioproducts. The journal emphasizes understanding and advancing the application of biotechnology and synergistic operations to improve plants and biological conversion systems for the biological production of these products from biomass, intermediates derived from biomass, or CO2, as well as upstream or downstream operations that are integral to biological conversion of biomass.
Biotechnology for Biofuels focuses on the following areas:
• Development of terrestrial plant feedstocks
• Development of algal feedstocks
• Biomass pretreatment, fractionation and extraction for biological conversion
• Enzyme engineering, production and analysis
• Bacterial genetics, physiology and metabolic engineering
• Fungal/yeast genetics, physiology and metabolic engineering
• Fermentation, biocatalytic conversion and reaction dynamics
• Biological production of chemicals and bioproducts from biomass
• Anaerobic digestion, biohydrogen and bioelectricity
• Bioprocess integration, techno-economic analysis, modelling and policy
• Life cycle assessment and environmental impact analysis
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