Laboratory of Microbiology, Wageningen University and Research, Wageningen, The Netherlands.
Systems and Synthetic Metabolism Group, Max Planck Institute of Molecular Plant Physiology, Potsdam-Golm, Germany.
Adv Biochem Eng Biotechnol. 2022;180:299-350. doi: 10.1007/10_2021_181.
In recent years the reductive glycine pathway (rGlyP) has emerged as a promising pathway for the assimilation of formate and other sustainable C1-feedstocks for future biotechnology. It was originally proposed as an attractive "synthetic pathway" to support formatotrophic growth due to its high ATP efficiency, linear structure, and limited overlap with native pathways in most microbial hosts. Here, we present the current state of research on this pathway including breakthroughs on its engineering. Different variants of the rGlyP are discussed, including its core module for formate to glycine conversion, as well as varying modules for substrate conversion to formate, and glycine assimilation routes. Very recently, the rGlyP has been successfully implemented for synthetic formatotrophic growth, as well as for growth on methanol, in some bacterial hosts. We discuss the engineering strategies employed in these studies, including growth-coupled selection of functional pathway modules. We also compare the rGlyP to other natural and synthetic C1-assimilation pathways. Finally, we provide an outlook on open challenges and opportunities for the rGlyP, including its engineering into more biotechnological hosts, as well as the still-to-be realized production of value-added chemicals via this pathway. We expect that further research on the rGlyP will support the efficient use of sustainable C1-substrates in bioproduction.
近年来,还原性甘氨酸途径(rGlyP)作为一种有前途的途径,用于同化甲酸盐和其他可持续的 C1 原料,以用于未来的生物技术。它最初被提议作为一种有吸引力的“合成途径”,以支持格式营养生长,因为它具有高 ATP 效率、线性结构,并且与大多数微生物宿主中的天然途径重叠有限。在这里,我们介绍了该途径的研究现状,包括其工程方面的突破。讨论了不同变体的 rGlyP,包括其将甲酸盐转化为甘氨酸的核心模块,以及将不同底物转化为甲酸盐和甘氨酸同化途径的变体模块。最近,rGlyP 已成功用于合成格式营养生长,以及一些细菌宿主中甲醇的生长。我们讨论了这些研究中采用的工程策略,包括与功能途径模块相关的生长耦合选择。我们还将 rGlyP 与其他天然和合成 C1 同化途径进行了比较。最后,我们对 rGlyP 面临的挑战和机遇进行了展望,包括将其工程应用于更多生物技术宿主,以及通过该途径实现有价值化学品的生产。我们期望对 rGlyP 的进一步研究将支持可持续 C1 底物在生物生产中的有效利用。
