具有生态多样性的 Phaeodactylum tricornutum 菌株的特定光照适应性、萜类化合物特征和工程潜力

Luca Morelli, Payal Patwari, Florian Pruckner, Maxime Bastide, Michele Fabris
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引用次数: 0

摘要

微藻类以及其中的硅藻--三角硅藻(Phaeodactylum tricornutum)以其显著的多功能性和代谢工程潜力而脱颖而出。硅藻在新陈代谢、光合生理和环境适应方面表现出很大的差异性,即使是同一物种也不例外。这些因素会影响代谢工程策略的设计和结果。在本研究中,我们分析了三种三尖杉菌株(Pt1、Pt6 和 Pt9)在不同光照条件下的生物技术相关性状的多样性,以确定最适合用作生物工厂生产高价值萜类化合物的底盘。我们对这些菌株进行了详细评估,使用脉冲幅度调制(PAM)荧光测定法测量光合效率,并分析了作为主要萜类代谢汇的色素和三萜类化合物的组成。我们利用 PSII 的最大量子产率(Fv/Fm)、激发能量捕获效率(Fv'/Fm')和 OJIP 动力学等参数来估计不同光照条件下的光合作用性能。此外,我们还以香叶醇为模型产品,评估了它们的转化效率及其生产异源单萜类化合物的能力。我们的研究结果表明,Pt1 被广泛应用于实验室,在标准实验室条件下表现出强劲的生长和光合作用性能。适应潮间带环境的 Pt6 在波动条件下表现出独特的适应能力,而耐高温的 Pt9 则在持续高辐照条件下表现出色。此外,不同菌株和光照条件下的这种差异性也影响了各菌株的代谢输出。我们的结论是,了解不同三 角柱虫菌株对光的生理反应,对于优化它们在代谢工程中的应用至关重要。从这项研究中获得的见解将有助于在藻类生物技术中战略性地选择和利用这些菌株,提高高价值萜类化合物和衍生物等有商业价值的化合物的产量。对不同光照条件下的菌株进行全面鉴定,为更高效、更有针对性的代谢工程应用提供了途径。
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Specific light-regime adaptations, terpenoid profiles and engineering potential in ecologically diverse Phaeodactylum tricornutum strains
Microalgae, and among them, the diatom Phaeodactylum tricornutum stand out with their remarkable versatility and metabolic engineering potential. Diatoms exhibit substantial variability in metabolism, photosynthetic physiology and environmental adaptation, even across the same species. These factors can affect the design and outcome of metabolic engineering strategies. In this study, we profiled the diversity of biotechnologically relevant traits of three P. tricornutum strains (Pt1, Pt6, and Pt9) under different light regimes to identify the most suitable chassis to be employed as bio-factory to produce high-value terpenoids. We conducted detailed assessments of these strains, using pulse amplitude modulated (PAM) fluorometry to measure photosynthetic efficiency and we analyzed the composition of pigments and triterpenoids, as main terpenoid metabolic sinks. Parameters such as the maximum quantum yield of PSII (Fv/Fm), the efficiency of excitation energy capture (Fv’/Fm’), and OJIP kinetics were used to estimate photosynthetic performance in different light regimes. Additionally, we evaluated their transformation efficiency and their capacity to produce heterologous monoterpenoids, using geraniol as a model product. Our findings revealed that Pt1, widely used in laboratories, exhibits robust growth and photosynthetic performance under standard laboratory conditions. Pt6, adapted to intertidal environments, shows unique resilience in fluctuating conditions, while Pt9, with its high-temperature tolerance, excels under continuous high irradiance. Additionally, this variability across strains and light conditions influenced the metabolic output of each strain. We concluded that understanding the physiological responses of different P. tricornutum strains to light is crucial for optimizing their use in metabolic engineering. The insights gained from this research will facilitate the strategic selection and exploitation of these strains in algae biotechnology, enhancing the production of commercially valuable compounds such as high-value terpenoids and derivatives. This comprehensive characterization of strains under varying light conditions offers a pathway to more efficient and targeted metabolic engineering applications.
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