Realisation of a key step in the evolution of C ₄ photosynthesis in rice by genome editing

C ₄ photosynthesis is a repeatedly evolved adaptation to photosynthesis that functions to reduce energy loss from photorespiration. The recurrent evolution of this adaptation is achieved through changes in the expression and localisation of several enzymes and transporters that are conventionally used in non-photosynthetic metabolism. These alterations result in the establishment of a biochemical CO ₂ pump that increases the concentration of CO ₂ around rubisco in a cellular environment where rubisco is protected from oxygen thus preventing the occurrence of photorespiration. A key step in the evolution of C ₄ photosynthesis is the change in subcellular localisation of carbonic anhydrase (CA) activity from the mesophyll cell chloroplast to the cytosol, where it catalyzes the first biochemical step of the C ₄ pathway. Here, we achieve this key step in C ₄ evolution in the C ₃ plant Oryza sativa (rice) using genome editing. We show that editing the chloroplast transit peptide of the primary CA isoform in the leaf results in relocalisation of leaf CA activity from the chloroplast to the cytosol. Through analysis of fluorescence induction kinetics in these CA relocalisation lines we uncover a role a new role for chloroplast CA in photosynthetic induction. We also reveal that relocalisation of CA activity to the cytosol causes no detectable perturbation to plant growth or leaf-level CO ₂ assimilation. Collectively, this work uncovers a novel role for chloroplast CA in C ₃ plants, and demonstrates that it is possible to achieve a key step in the evolution of C ₄ photosynthesis by genome editing.