Oleaginous Yeast Biology Elucidated With Comparative Transcriptomics

IF 3.5 2区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biotechnology and Bioengineering Pub Date : 2024-12-10 DOI:10.1002/bit.28891

Sarah J. Weintraub, Zekun Li, Carter L. Nakagawa, Joseph H. Collins, Eric M. Young

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Abstract

Extremophilic yeasts have favorable metabolic and tolerance traits for biomanufacturing- like lipid biosynthesis, flavinogenesis, and halotolerance – yet the connection between these favorable phenotypes and strain genotype is not well understood. To this end, this study compares the phenotypes and gene expression patterns of biotechnologically relevant yeasts Yarrowia lipolytica, Debaryomyces hansenii, and Debaryomyces subglobosus grown under nitrogen starvation, iron starvation, and salt stress. To analyze the large data set across species and conditions, two approaches were used: a “network-first” approach where a generalized metabolic network serves as a scaffold for mapping genes and a “cluster-first” approach where unsupervised machine learning co-expression analysis clusters genes. Both approaches provide insight into strain behavior. The network-first approach corroborates that Yarrowia upregulates lipid biosynthesis during nitrogen starvation and provides new evidence that riboflavin overproduction in Debaryomyces yeasts is overflow metabolism that is routed to flavin cofactor production under salt stress. The cluster-first approach does not rely on annotation; therefore, the coexpression analysis can identify known and novel genes involved in stress responses, mainly transcription factors and transporters. Therefore, this work links the genotype to the phenotype of biotechnologically relevant yeasts and demonstrates the utility of complementary computational approaches to gain insight from transcriptomics data across species and conditions.

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用比较转录组学阐明产油酵母生物学

嗜极酵母在生物制造中具有良好的代谢和耐受性，如脂质生物合成、黄酮生成和耐盐性，但这些有利表型与菌株基因型之间的联系尚不清楚。为此，本研究比较了生物技术相关酵母在氮饥饿、铁饥饿和盐胁迫下生长的多脂耶氏酵母（Yarrowia lipolytica）、汉斯德巴氏酵母（Debaryomyces hansenii）和亚球形德巴氏酵母（Debaryomyces subglobosus）的表型和基因表达模式。为了分析跨物种和条件的大型数据集，使用了两种方法：一种是“网络优先”方法，其中广义代谢网络作为基因定位的支架，另一种是“集群优先”方法，其中无监督机器学习共表达分析聚类基因。这两种方法都提供了对应变行为的洞察。网络优先的方法证实了耶氏菌在氮饥饿期间上调脂质生物合成，并提供了新的证据，证明Debaryomyces酵母中核黄素的过量生产是盐胁迫下黄素辅助因子生产的溢出代谢。集群优先的方法不依赖于注释；因此，共表达分析可以识别已知的和新的参与应激反应的基因，主要是转录因子和转运蛋白。因此，这项工作将基因型与生物技术相关酵母的表型联系起来，并展示了互补计算方法在跨物种和条件的转录组学数据中获得洞察力的实用性。

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来源期刊

Biotechnology and Bioengineering 工程技术-生物工程与应用微生物

CiteScore

7.90

自引率

5.30%

发文量

280

审稿时长

2.1 months

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