Non-Monotone Response Modules and Cascades from the EML Operator for Reduced Models of Biological Dynamics
TLDR
A new EML operator enables single-block non-monotone response modules for reduced biological models, efficiently capturing complex dynamics like overshoot.
Key contributions
- Introduces the EML operator as a structured grammar for reduced nonlinear ODEs in biological dynamics.
- Develops an activation-suppression module using EML that directly captures non-monotone responses like overshoot.
- Validates EML's ability to discover reduced models consistent with biology and compress complex networks.
Why it matters
Current biological models struggle with non-monotone responses using single blocks, requiring complex multi-block setups. This paper offers a simpler, more efficient approach using the EML operator. It significantly reduces model complexity while accurately capturing crucial biological dynamics like overshoot, making it valuable for understanding and modeling complex systems.
Original Abstract
Standard saturating response functions, such as the Hill function, are monotone and therefore cannot represent recruitment-induced overshoot or adaptive transients with a single block. Reproducing such non-monotone responses from saturating primitives requires at least a difference of two blocks with opposing amplitudes, doubling the static-block parameter count. Here, building on a recent mathematical result that a single binary operator, EML, generates all standard elementary functions, we use EML as a structured grammar for reduced nonlinear ODEs. This yields an activation-suppression module that captures overshoot directly. We validate the framework in three settings. First, on PKA-R relocalization data, the EML grammar discovers a reduced surrogate consistent with established mechanistic biology. Second, on Rho-GTPase recruitment data, an exhaustive search over EML expression trees selects the same compositional form across all four perturbation-response traces. Third, a 50-state simulated network is compressed by an EML cascade acting as a fixed temporal basis. Thus we demonstrate the power and potential of EML for reduced models of biological dynamics.
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