Modification of photosynthesis systems
光合系统改造

Project Profile 项目简介

AI-driven Rubisco engineering, novel carbon-fixation enzyme design, and the construction of synthetic carbon fixation cycles are employed to build artificial multi-enzyme complexes for substrate compartmentalization, thereby synergistically optimizing photosynthetic efficiency and key metabolic fluxes (Qin et al., 2025, Journal of Integrative Plant Biology; Zhao et al., 2025, Current Opinion in Plant Biology).

基于AI驱动的Rubisco改造，新型固碳酶设计和新型碳固定循环设计，构建人工多酶复合体实现底物区室化，以协同优化光合效率与关键代谢通量 （Qin et al., 2025, Journal of Integrative Plant Biology; Zhao et al., 2025, Current Opinion in Plant Biology）。

代表性成果

1. Qin K., Ye X., Luo S., Fernie A. R., & Zhang Y. (2025). Engineering Carbon Assimilation in Plants. Journal of Integrative Plant Biology, 67: 926–948.
2. Zhao Z., Fernie A. R., & Zhang Y. (2025). Engineering Nitrogen and Carbon Fixation for Next-generation Plants. Current Opinion in Plant Biology, 85, 102699.

Project Figure 项目图