Generation and comprehensive analysis of Synechococcus elongatus-Aspergillus nidulans co-culture system for polyketide production.

Biotechnology for Biofuels and Bioproducts Pub Date : 2023-03-01 DOI:10.1186/s13068-023-02283-6

Jie Feng, Jingwei Li, Dongxia Liu, Yuxian Xin, Jingrong Sun, Wen-Bing Yin, Tingting Li

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Abstract

Background: Artificial microbial consortia composed of heterotrophic and photoautotrophic organisms represent a unique strategy for converting light energy and carbon dioxide into high-value bioproducts. Currently, the types of desired bioproducts are still limited, and microbial fitness benefit rendered by paired partner generally needs to be intensified. Exploring novel artificial microbial consortia at a laboratory scale is an essential step towards addressing this unmet need. This study aimed to conduct and analyze an artificial consortium composed of cyanobacterium Synechococcus elongatus FL130 with the filamentous fungus Aspergillus nidulans TWY1.1 for producing fungi-derived secondary metabolite of polyketide neosartoricin B.

Results: Polyketide-producing A. nidulans TWY1.1 substantially ameliorated the growth and the survival of sucrose-secreting cyanobacterium S. elongatus FL130 in salt-stressed environments. Besides sucrose, comparable amounts of other carbohydrates were released from axenically cultured FL130 cells, which could be efficiently consumed by TWY1.1. Relative to axenically cultured FL130, less glycogen was accumulated in FL130 cells co-cultured with TWY1.1, and the glycogen phosphorylase gene catalyzing the first step for glycogen degradation had two-fold expression. Different from axenically cultured filamentous fungi, abundant vacuoles were observed in fungal hyphae of TWY1.1 co-cultured with cyanobacterium FL130. Meanwhile, FL130 cells displayed a characteristic pattern of interacting with its heterotrophic partner, densely dispersing along certain hyphae of TWY1.1. Finally, polyketide neosartoricin B was produced from TWY1.1 in FL130-TWY1.1 co-cultures, which was tightly adjusted by nitrogen level.

Conclusion: Overall, the results thoroughly proved the concept of pairing cyanobacteria with filamentous fungi to build artificial consortia for producing fungi-derived biomolecules.

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长聚球菌-中性曲霉共培养体系的生成及综合分析。

背景:由异养和光自养生物组成的人工微生物联合体代表了将光能和二氧化碳转化为高价值生物产品的独特策略。目前，期望的生物制品类型仍然有限，并且通常需要加强配对伙伴所带来的微生物适应度效益。在实验室规模上探索新型人工微生物联合体是解决这一未满足需求的重要一步。本研究旨在对由长聚球菌FL130与丝状真菌灰曲霉TWY1.1组成的人工联合体进行分析，以产生聚酮类新桃素b的真菌衍生次生代谢物。结果:产聚酮类灰曲霉TWY1.1可显著改善分泌蔗糖的蓝细菌S. elongatus FL130在盐胁迫环境下的生长和存活。除了蔗糖外，体外培养的FL130细胞还释放出相当数量的其他碳水化合物，这些碳水化合物可以被TWY1.1有效地消耗。与异体培养FL130相比，与TWY1.1共培养FL130细胞中积累的糖原较少，催化糖原降解第一步的糖原磷酸化酶基因双表达。与体外培养的丝状真菌不同，与蓝藻FL130共培养的TWY1.1菌丝中有大量的液泡。同时，FL130细胞表现出与其异养伴侣相互作用的特征模式，沿着TWY1.1的某些菌丝密集分散。最后，在FL130-TWY1.1共培养条件下，由TWY1.1产生聚酮类新石蒜素B。结论:总体而言，研究结果充分证明了蓝藻与丝状真菌配对构建人工联合体生产真菌源生物分子的概念。

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Biotechnology for Biofuels and Bioproducts

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