Noise-guided tuning of synthetic protein waves in living cells

Biological systems use protein circuits to organize cellular activities in space and time, but engineering synthetic dynamics is challenging due to stochastic effects of genetic and biochemical variation on circuit behavior. Genetically encoded oscillators (GEOs) built from bacterial MinDE-family ATPase and Activator modules generate fast orthogonal protein waves in eukaryotic cells, providing an experimental model system for genetic and biochemical coordination of synthetic protein dynamics. Here, we use budding yeast to experimentally define and model phase portraits that reveal how the breadth of frequencies and amplitudes available to a GEO are genetically controlled by ATPase and Activator expression levels and noise. GEO amplitude is encoded by ATPase absolute abundance, making it sensitive to extrinsic noise on a population level. In contrast, GEO frequency is remarkably stable because it is controlled by the Activator:ATPase ratio and thus affected primarily by intrinsic noise. These features facilitate noise-guided design of different expression strategies that act as filters on GEO waveform, enabling us to construct clonal populations that oscillate at different frequencies as well as independently tune frequency and amplitude variation within a single population. By characterizing 169 biochemically distinct GEOs, we provide a rich assortment of phase portraits as starting points for application of our waveform engineering approach. Our findings suggest noise-guided design may be a valuable strategy for achieving precision control over dynamic protein circuits.