Impact of Acetate and Optimized Nitrate Levels on Mixotrophic Growth and Protein Dynamics in Chlorella Sorokiniana

bioRxiv - Bioengineering Pub Date : 2024-09-07 DOI:10.1101/2024.09.04.611160

Sunni Chen, Ruiqi Wang, Youn Joong Kim, Emily Radican, Yu Lei, Yong Ku Cho, Zhenlei Xiao, Mingyu Qiao, Yangchao Luo

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Abstract

Microalgae are well-known for their role as sustainable bio-factories, offering a promising solution to the global food and nutrition crisis. To clarify the potential of Chlorella sorokiniana UTEX 1230 for food applications, particularly as an alternative protein source, the study employed a mixotrophic cultivation mode with sodium acetate (NaAc) as a cost-effective organic carbon (NaAc-C) source. Varying levels of NaAc-C and nitrate-sourced nitrogen were investigated, optimizing the effect of metabolic characteristics of the microalgal growth. The designed heterotrophic cultivation confirmed the ability of C. sorokiniana UTEX 1230 to grow on NaAc-C, and then the mixotrophic cultures, when supported by both NaAc-C and CO2, exhibited superior growth performance, achieving double the biomass concentration compared to the autotrophic control. The addition of nitrogen (750 mg/L NaNO₃) facilitated the thorough metabolism of NaAc-C and enhanced photosynthetic activity indicated by a 196% increase in pigment levels, which resulted in a maximum biomass concentration of 2.82 g/L in the 150 mM NaAc-C group. A detailed analysis of nitrogen and protein concentrations over time revealed that higher nitrogen availability led to greater protein accumulation which was then degraded to support essential life activities under nitrogen starvation. Therefore, it is suggested that supplementing nitrate on the 3rd day and harvesting on the 4th day could be strategically implemented to increase protein yield from 0.17 g/L/d to 0.34 g/L/d. These findings offer theoretical guidance for further refining this microalgal strain for use as an alternative protein.

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醋酸盐和优化硝酸盐水平对索罗金亚纳小球藻混养生长和蛋白质动力学的影响

微藻以其作为可持续生物工厂的作用而闻名，为解决全球粮食和营养危机提供了一种前景广阔的解决方案。为了明确小球藻 UTEX 1230 在食品应用方面的潜力，特别是作为替代蛋白质来源的潜力，该研究采用了以醋酸钠（NaAc）作为具有成本效益的有机碳（NaAc-C）来源的混养培养模式。研究了不同水平的 NaAc-C 和硝酸盐源氮，以优化微藻生长代谢特性的影响。所设计的异养培养证实了 C. sorokiniana UTEX 1230 在 NaAc-C 上的生长能力，然后在 NaAc-C 和 CO2 的支持下，混养培养物表现出更优越的生长性能，生物量浓度比自养对照高出一倍。氮（750 毫克/升 NaNO₃）的添加促进了 NaAc-C 的彻底代谢，并增强了光合作用活性，表现为色素水平增加了 196%，150 毫摩尔 NaAc-C 组的最大生物量浓度为 2.82 克/升。对氮和蛋白质浓度随时间变化的详细分析显示，较高的氮供应量导致更多的蛋白质积累，然后在氮饥饿条件下，蛋白质被降解以支持必要的生命活动。因此，建议战略性地在第 3 天补充硝酸盐，第 4 天收获，以将蛋白质产量从 0.17 克/升/天提高到 0.34 克/升/天。这些发现为进一步改进这种微藻菌株以用作替代蛋白质提供了理论指导。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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bioRxiv - Bioengineering

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