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Engineering precise synthetic circuits and what it can teach us about biology

Laurent Potvin-Trottier

Concordia University

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Engineering synthetic biological systems holds the potential for valuable applications, ranging from environmental remediation to biomedicine. It can also deepen our fundamental understanding of natural phenomena, by building gene circuits and biological systems from the bottom up. Synthetic gene circuits are able to perform a variety of useful tasks, but despite being made from well-characterized biological components, their precision and robustness are usually much lower than their natural counterparts. Our hypothesis for this difference is that synthetic circuits have so far been designed mostly without accounting for the inherent stochastic gene expression in living cells.

To demonstrate this, I will show how harnessing principles from stochastic theory to redesign a classic synthetic oscillator (the repressilator, which helped jump-start the field of synthetic biology) helped produce oscillations that rival those of natural clocks. I will then describe how this motivated us to engineer hundreds of oscillators using a newly developed method for screening dynamical phenotypes, thus allowing us to explore areas that are beyond our current theoretical understanding. Finally, I will showcase applications of synthetic circuits to study natural systems, such as measuring bacterial growth in the gut of live mice and measuring protein degradation in single cells, and discuss the biological insights learned by engineering precise synthetic circuits.