Perspectives on improving crop Rubisco by directed evolution.

Rubisco catalyses the entry of almost all CO 2 into the biosphere and is often the rate-limiting step in plant photosynthesis and growth. Its notoriety as the most abundant protein on Earth stems from the slow and error-prone catalytic properties that require plants, cyanobacteria, algae and photosynthetic bacteria to produce it in high amounts. Efforts to improve the CO 2 -fixing properties of plant Rubisco has been spurred on by the discovery of more effective isoforms in some algae with the potential to significantly improve crop productivity. Incompatibilities between the protein folding machinery of leaf and algae chloroplasts have, so far, prevented efforts to transplant these more effective Rubisco variants into plants. There is therefore increasing interest in improving Rubisco catalysis by directed (laboratory) evolution. Here we review the advances being made in, and the ongoing challenges with, improving the solubility and/or carboxylation activity of differing non-plant Rubisco lineages. We provide perspectives on new opportunities for the directed evolution of crop Rubiscos and the existing plant transformation capabilities available to evaluate the extent to which Rubisco activity improvements can benefit agricultural productivity. • The catalysis of Rubisco from different lineages can be improved by directed evolution. • New Escherichia coli selection tools now make possible the directed evolution of Rubisco from dicot plants. • Bioengineering crop Rubisco remains limited by the number of species amenable to chloroplast transformation. [ABSTRACT FROM AUTHOR]