Metabolic optogenetics as a new paradigm to study and engineer metabolism

Optogenetics uses light-responsive proteins to control biological processes. The unmatched spatiotemporal precision, high tunability, reversibility, and few side effects of light makes  optogenetics a powerful strategy to study and engineer complex biological systems. For these  reasons, optogenetics has already revolutionized disciplines such as neuroscience,  developmental biology, and cell signaling, and is poised to do the same with cellular metabolism. I will show several classes of transcriptional optogenetic circuits that we have developed to control metabolic pathwaysfor chemical production in Saccharomyces cerevisiae and Escherichia  coli. Additionally, I will present optogenetic strategies to achieve post-translational regulation of  metabolism, including light-controlled synthetic metabolic organelles, and optical binders. One  of the most exciting prospects of metabolic optogenetics is combining optogenetic regulators with genetically encoded biosensor to achieve closed-loop controls of metabolism. I will present  the progress we have made towards this goal, including rapid optogenetic circuits, and new  biosensors that can function in combination with optogenetic controls in the same strain. I will  discuss the challenges that lay ahead and the opportunities to overcome them to realize the full  potential of metabolic optogenetics.