Mixed positive and negative feedback loops drive diverse single-cell gene expression dynamics

Genetic circuits with only a few components can generate complex gene regulatory dynamics. Here, we combine stochastic modelling and single-cell time-lapse microscopy to reveal the possible dynamics generated by a key gene circuit motif: the mixed positive/negative feedback loop. Our minimal stochastic model of this motif reveals ten distinct classes of dynamic output, including stochastic pulsing, oscillations, and bistability. These dynamics are influenced by only a few important biological parameters, such as the strength of the positive and negative feedbacks. Experimental validation in two different mixed feedback circuits in the bacterium B. subtilis , σ ^B and σ ^V , confirms our model’s predictive power. Guided by our simulations, we are able to transition between dynamic behaviours by modulating in vivo parameters. Together, these results demonstrate how mixed feedback loops generate diverse single-cell behaviours, improving our understanding of this common biological network motif and informing our efforts to engineer them for synthetic biology applications.