Phosphate limitation as crucial factor to enhance yeast lipid production from short-chain fatty acids

IF 4.8 2区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Microbial Biotechnology Pub Date : 2022-12-19 DOI:10.1111/1751-7915.14197
Sergio Morales-Palomo, Elia Tomás-Pejó, Cristina González-Fernández
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引用次数: 3

Abstract

Microbial lipids for chemical synthesis are commonly obtained from sugar-based substrates which in most cases is not economically viable. As a low-cost carbon source, short-chain fatty acids (SCFAs) that can be obtained from food wastes offer an interesting alternative for achieving an affordable lipid production process. In this study, SCFAs were employed to accumulate lipids using Yarrowia lipolytica ACA DC 50109. For this purpose, different amounts of SCFAs, sulfate, phosphate and carbon: phosphate ratios were used in both synthetic and real SCFAs-rich media. Although sulfate limitation did not increase lipid accumulation, phosphate limitation was proved to be an optimal strategy for increasing lipid content and lipid yields in both synthetic and real media, reaching a lipid productivity up to 8.95 g/L h. Remarkably, the highest lipid yield (0.30 g/g) was achieved under phosphate absence condition (0 g/L). This fact demonstrated the suitability of using low-phosphate concentrations to boost lipid production from SCFAs.

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磷酸盐限制是提高酵母短链脂肪酸产脂的关键因素
用于化学合成的微生物脂质通常是从糖基底物中获得的,在大多数情况下,这在经济上是不可行的。作为一种低成本的碳源,短链脂肪酸(SCFAs)可以从食物垃圾中获得,为实现经济实惠的脂质生产过程提供了一个有趣的选择。在本研究中,利用聚脂耶氏菌ACA DC 50109,利用scfa积累脂质。为此,在合成和真正的富scfa培养基中使用了不同数量的scfa、硫酸盐、磷酸盐和碳:磷酸盐比例。虽然硫酸盐限制不会增加脂质积累,但磷酸盐限制被证明是提高合成和真实培养基中脂质含量和脂质产量的最佳策略,脂质产量高达8.95 g/L h。在无磷条件下(0 g/L)脂质产量最高,为0.30 g/g。这一事实证明了使用低磷酸盐浓度促进scfa脂质生成的适用性。
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来源期刊
Microbial Biotechnology
Microbial Biotechnology BIOTECHNOLOGY & APPLIED MICROBIOLOGY-MICROBIOLOGY
CiteScore
9.80
自引率
3.50%
发文量
162
审稿时长
6-12 weeks
期刊介绍: Microbial Biotechnology publishes papers of original research reporting significant advances in any aspect of microbial applications, including, but not limited to biotechnologies related to: Green chemistry; Primary metabolites; Food, beverages and supplements; Secondary metabolites and natural products; Pharmaceuticals; Diagnostics; Agriculture; Bioenergy; Biomining, including oil recovery and processing; Bioremediation; Biopolymers, biomaterials; Bionanotechnology; Biosurfactants and bioemulsifiers; Compatible solutes and bioprotectants; Biosensors, monitoring systems, quantitative microbial risk assessment; Technology development; Protein engineering; Functional genomics; Metabolic engineering; Metabolic design; Systems analysis, modelling; Process engineering; Biologically-based analytical methods; Microbially-based strategies in public health; Microbially-based strategies to influence global processes
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