When green carbon plants meet synthetic biology

International Journal of Modern Agriculture Pub Date : 2023-10-31 DOI:10.1002/moda.17

Qing Wang, Jianfeng Zhang, Qiulan Dai, Meijie Cui, Hao Yang, Peijian Cao, Lei Zhao

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Abstract

Abstract Recycling carbon dioxide (CO 2 ) into chemicals or fuels presents a promising avenue for mitigating carbon emissions and addressing the energy crisis. Plants serve as the ideal platform for the production of materials and chemicals, thanks to their innate capacity to directly use CO 2 in the synthesis of various organic compounds. While conventional methods for enhancing plant CO 2 fixation may reach their limits, novel technological solutions are imperative. Synthetic biology has illuminated the potential for biosynthesising multiple carbon sources through artificial CO 2 fixation pathways in vitro. Recent breakthroughs in photorespiratory bypasses and artificial carboxylation modules offer significant promise for engineering plants to improve carbon fixation, guiding the design and development of plants with more efficient CO 2 utilisation. In this context, we begin by summarising recent progress in designing or engineering in vitro CO 2 fixation pathways, as well as those solely established in microbes. Subsequently, we delineate strategies employed to enhance CO 2 fixation in plants. Finally, we explore potential methods for introducing artificial CO 2 fixation pathways into plants. These advancements are critical in advancing synthetic biology's efforts to tackle future challenges related to food and energy scarcity.

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当绿色碳植物遇到合成生物学

摘要:回收二氧化碳(CO 2)到化学品或燃料提出了一个有希望的途径，以减少碳排放和解决能源危机。植物是生产材料和化学品的理想平台，因为它们天生具有直接利用二氧化碳合成各种有机化合物的能力。虽然提高植物二氧化碳固定的传统方法可能达到极限，但新的技术解决方案势在必行。合成生物学已经阐明了通过体外人工co2固定途径生物合成多种碳源的潜力。最近在光呼吸旁路和人工羧化模块方面的突破为工程植物提供了改善碳固定的重大希望，指导了更有效利用二氧化碳的植物的设计和开发。在这种背景下，我们首先总结了最近在设计或工程的体外co2固定途径方面的进展，以及那些仅在微生物中建立的途径。随后，我们描述了增强植物对二氧化碳固定的策略。最后，我们探讨了将人工co2固定途径引入植物体内的潜在方法。这些进步对于推进合成生物学应对未来与粮食和能源短缺相关的挑战至关重要。

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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来源期刊

International Journal of Modern Agriculture AGRONOMY-

自引率

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发文量

438