Comparative transcriptome analysis reveals the redirection of metabolic flux from cell growth to astaxanthin biosynthesis in Yarrowia lipolytica

IF 2.2 4区 生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY
Yeast Pub Date : 2024-04-13 DOI:10.1002/yea.3938
Dan‐Ni Wang, Chen‐Xi Yu, Jie Feng, Liu‐Jing Wei, Jun Chen, Zhijie Liu, Liming Ouyang, Lixin Zhang, Feng Liu, Qiang Hua
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Abstract

Engineering Yarrowia lipolytica to produce astaxanthin provides a promising route. Here, Y. lipolytica M2 producing a titer of 181 mg/L astaxanthin was isolated by iterative atmospheric and room‐temperature plasma mutagenesis and diphenylamine‐mediated screening. Interestingly, a negative correlation was observed between cell biomass and astaxanthin production. To reveal the underlying mechanism, RNA‐seq analysis of transcriptional changes was performed in high producer M2 and reference strain M1, and a total of 1379 differentially expressed genes were obtained. Data analysis revealed that carbon flux was elevated through lipid metabolism, acetyl‐CoA and mevalonate supply, but restrained through central carbon metabolism in strain M2. Moreover, upregulation of other pathways such as ATP‐binding cassette transporter and thiamine pyrophosphate possibly provided more cofactors for carotenoid hydroxylase and relieved cell membrane stress caused by astaxanthin insertion. These results suggest that balancing cell growth and astaxanthin production may be important to promote efficient biosynthesis of astaxanthin in Y. lipolytica.

Abstract Image

比较转录组分析揭示了脂肪溶解亚罗维氏菌中从细胞生长到虾青素生物合成的代谢通量的重新定向
对脂肪溶解蓍草菌进行工程改造以生产虾青素是一条很有前景的途径。在这里,通过大气和室温等离子体诱变迭代以及二苯胺介导的筛选,分离出了可产生 181 毫克/升虾青素滴度的脂溶性酵母菌 M2。有趣的是,细胞生物量与虾青素产量之间呈负相关。为揭示其潜在机制,对高产菌株 M2 和参考菌株 M1 的转录变化进行了 RNA-seq 分析,共获得 1379 个差异表达基因。数据分析显示,在菌株 M2 中,碳通量通过脂质代谢、乙酰-CoA 和甲羟戊酸供应得到提高,但通过中心碳代谢受到抑制。此外,ATP 结合盒转运体和焦磷酸硫胺素等其他途径的上调可能为类胡萝卜素羟化酶提供了更多辅助因子,并缓解了虾青素插入造成的细胞膜压力。这些结果表明,平衡细胞生长和虾青素生产可能对促进溶脂酵母中虾青素的高效生物合成非常重要。
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来源期刊
Yeast
Yeast 生物-生化与分子生物学
CiteScore
5.30
自引率
3.80%
发文量
55
审稿时长
3 months
期刊介绍: Yeast publishes original articles and reviews on the most significant developments of research with unicellular fungi, including innovative methods of broad applicability. It is essential reading for those wishing to keep up to date with this rapidly moving field of yeast biology. Topics covered include: biochemistry and molecular biology; biodiversity and taxonomy; biotechnology; cell and developmental biology; ecology and evolution; genetics and genomics; metabolism and physiology; pathobiology; synthetic and systems biology; tools and resources
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