Resolving Emergent Oscillations in Gene Circuits with a Growth-Coupled Model

Synthetic gene circuits often behave unpredictably in batch cultures, where shifting physiological states are rarely accounted for in conventional models. Here, we report the emergence of oscillatory expression dynamics in degradation-tagged protein reporters, an unexpected phenomenon that contradicts predictions from standard single-scale models. We resolve this discrepancy by developing GEAGS (Gene Expression Across Growth Stages), a dual-scale modeling framework that explicitly couples intracellular gene expression to logistic population growth. Using a chemical reaction network (CRN) model with growth-phase-dependent rate-modifying functions, GEAGS accurately reproduces the observed oscillations and identifies amino acid recycling and growth phase transition as key drivers. We reduce the model to an effective form for practical use and demonstrate its adaptability by applying it to layered feedback circuits, resolving longstanding mismatches between model predictions and measured dynamics. These results establish GEAGS as a generalizable platform for predicting emergent behaviors in synthetic gene circuits and underscore the importance of multiscale modeling for robust circuit design in dynamic environments.