As important oxygenic photoautotrophs, cyanobacteria are also generally considered as one of the most promising microbial chassis for photosynthetic biomanufacturing. Diverse synthetic biology and metabolic engineering approaches have been developed to enable the efficient harnessing of carbon and energy flow toward the synthesis of desired metabolites in cyanobacterial cell factories. Glycogen metabolism works as the most important natural carbon sink mechanism and reserve carbon source, storing a large portion of carbon and energy from the Calvin-Benson-Bassham (CBB) cycle, and thus is traditionally recognized as a promising engineering target to optimize the efficacy of cyanobacterial cell factories. Multiple strategies and approaches have been designed and adopted to engineer glycogen metabolism in cyanobacteria, leading to the successful regulation of glycogen synthesis and storage contents in cyanobacteria cells. However, disturbed glycogen metabolism results in weakened cellular physiological functionalities, thereby diminishing the robustness of metabolism. In addition, the effects of glycogen removal as a metabolic engineering strategy to enhance photosynthetic biosynthesis are still controversial. This review focuses on the efforts and effects of glycogen metabolism engineering on the physiology and metabolism of cyanobacterial chassis strains and cell factories. The perspectives and prospects provided herein are expected to inspire novel strategies and tools to achieve ideal control over carbon and energy flow for biomanufacturing.
Keywords: Cellular robustness; Cyanobacteria; Glycogen; Metabolic engineering; Metabolism; Photosynthesis; Photosynthetic biomanufacturing; Physiology.
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