Physiological Metabolic Analysis of VB12 Accumulation in Ensifer adhaerens Casida A Enhanced by Oxygen Limitation

IF 3.2 3区生物学 Q2 BIOCHEMICAL RESEARCH METHODS

Biotechnology Journal Pub Date : 2024-09-19 DOI:10.1002/biot.202400305

Bo Li, Xinyi Chen, Dujuan Zhao, Zebo Liu, Junming Li, Muhammad Safwan Siddique, Jiequn Wu, Yingping Zhuang, Zejian Wang

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Abstract

Cobalamin (VB₁₂) is in enormous demand across the fields of medicine, food, and feed additives. However, the oxygen supply plays a critical role in VB₁₂ biosynthesis by Ensifer adhaerens Casida A and has been identified as a bottleneck for economical substrate consumption. This study elucidates the relationship between oxygen limitation and VB₁₂ accumulation with transcriptomic and metabolomic analyses. Under oxygen limitation, E. adhaerens enhances oxygen transport and storage by increasing expression of flavin hemoglobin (Hmp), which was up-regulated 6-fold at 24 h of oxygen restriction compared to the oxygen restriction of 4 h (p < 0.01). Because of the cofactor of Hmp is heme, the demand for heme increases, leading to the upregulation of genes in the heme biosynthesis pathway. Similarly, genes involved in biosynthesis of its precursor, 5-ALA, were upregulated as well. 5-ALA is also a direct precursor of VB₁₂, further leading to the upregulation of genes in the VB₁₂ biosynthesis pathway. This process initiates biosynthesis and accumulation of VB₁₂. As VB₁₂ and heme biosynthesis progresses, genes associated with the biosynthesis and transportation pathways of compounds related to their biosynthesis were likewise upregulated, including genes involved in S-adenosyl methionine (SAM) biosynthesis, and the transport of Fe²⁺ and Co²⁺. Additionally, amino acids and organic acids associated with biosynthesis were also extensively consumed, such as methionine, which is used for synthesizing SAM, decreased by 310% after 24 h of oxygen limitation compared to 20% dissolved oxygen (p < 0.05). At the same time, genes related to growth-associated metabolic pathways, such as pentose phosphate pathway (PPP), were significantly downregulated. Therefore, the potential mechanism by which E. adhaerens accumulates VB₁₂ under oxygen-limited conditions by enhancing Hmp expression, which facilitates the porphyrin metabolic pathway and promotes VB₁₂ biosynthesis. This research provides valuable insights for increasing VB₁₂ production through metabolic engineering and process optimization.

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氧限制对 Ensifer adhaerens Casida A 中 VB12 积累的生理代谢分析。

钴胺素（VB12）在医药、食品和饲料添加剂等领域的需求量巨大。然而，氧气供应在 Ensifer adhaerens Casida A 的 VB12 生物合成过程中起着至关重要的作用，并已被确定为经济底物消耗的瓶颈。本研究通过转录组和代谢组分析，阐明了氧限制与 VB12 积累之间的关系。在氧限制条件下，E. adhaerens 通过增加黄素血红蛋白（Hmp）的表达来提高氧的运输和储存，与氧限制 4 小时相比，氧限制 24 小时时 Hmp 的表达上调了 6 倍（p < 0.01）。由于 Hmp 的辅助因子是血红素，因此对血红素的需求增加，导致血红素生物合成途径中的基因上调。同样，参与其前体 5-ALA 生物合成的基因也被上调。5-ALA 也是 VB12 的直接前体，进一步导致 VB12 生物合成途径中的基因上调。这一过程启动了 VB12 的生物合成和积累。随着 VB12 和血红素生物合成的进行，与其生物合成有关的化合物的生物合成和运输途径相关的基因也同样上调，包括参与 S-腺苷蛋氨酸（SAM）生物合成以及 Fe2+ 和 Co2+ 运输的基因。此外，与生物合成相关的氨基酸和有机酸也被大量消耗，如用于合成 SAM 的蛋氨酸在氧气限制 24 小时后比溶解氧为 20% 时减少了 310%（p < 0.05）。同时，与生长相关的代谢途径（如磷酸戊糖途径（PPP））有关的基因也显著下调。因此，E. adhaerens 在氧限制条件下积累 VB12 的潜在机制是通过增强 Hmp 的表达，从而促进卟啉代谢途径并促进 VB12 的生物合成。这项研究为通过代谢工程和工艺优化提高 VB12 产量提供了宝贵的见解。

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来源期刊

Biotechnology Journal Biochemistry, Genetics and Molecular Biology-Molecular Medicine

CiteScore

8.90

自引率

2.10%

发文量

123

审稿时长

1.5 months

期刊介绍： Biotechnology Journal (2019 Journal Citation Reports: 3.543) is fully comprehensive in its scope and publishes strictly peer-reviewed papers covering novel aspects and methods in all areas of biotechnology. Some issues are devoted to a special topic, providing the latest information on the most crucial areas of research and technological advances. In addition to these special issues, the journal welcomes unsolicited submissions for primary research articles, such as Research Articles, Rapid Communications and Biotech Methods. BTJ also welcomes proposals of Review Articles - please send in a brief outline of the article and the senior author''s CV to the editorial office. BTJ promotes a special emphasis on: Systems Biotechnology Synthetic Biology and Metabolic Engineering Nanobiotechnology and Biomaterials Tissue engineering, Regenerative Medicine and Stem cells Gene Editing, Gene therapy and Immunotherapy Omics technologies Industrial Biotechnology, Biopharmaceuticals and Biocatalysis Bioprocess engineering and Downstream processing Plant Biotechnology Biosafety, Biotech Ethics, Science Communication Methods and Advances.