A General Framework for Designing Evolutionary Experiments to Select Specific Phage Phenotypes Using Neural Networks, Statistical Simulations, and Symbolic Regression.
Oral-In-person
Abstract
Understanding how environmental conditions shape the evolution of bacteriophages (phages) is critical for designing correct evolutionary experiments that select specific phage traits. This study provides a general mathematical framework that integrates physics-informed neural networks, agent-based statistical simulations, and symbolic regression machine learning techniques to design evolutionary experiments targeting specific phage traits such as high variability in phage phenotypes.
In the study, we used agent-based statistical simulations to generate synthetic time series data for evolutionary scenarios with diverse phenotypic outcomes. Subsequently, we trained Physics-informed neural networks (PINNs) embedded in differential equations on the synthetic time series to reveal possible environments that select given phage traits and uncovered hidden interactions in the system [1].
Lastly, by using symbolic regression techniques, including Sparse Identification of Nonlinear Dynamical Systems (SINDy) and genetic algorithm-based methods, on the synthetic time series data, we derived governing differential equations that identified key environmental conditions and interaction pathways driving the evolution of specific phage traits in well-mixed and spatiotemporal microbial systems. These equations serve as a foundation for predicting the correct evolutionary experiment to select for the given phage traits.
This approach provides a scalable and adaptable framework for designing evolutionary experiments to select specific phage phenotypes. It highlights the power of integrating physics-informed neural networks, agent-based simulations, and symbolic regression techniques to offer new insights into the mechanisms underlying complex microbial ecosystems.
Reference:
[1] Grigorian, G., George, S.V. and Arridge, S., 2024. Learning Governing Equations of Unobserved States in Dynamical Systems. arXiv preprint arXiv:2404.18572.
In the study, we used agent-based statistical simulations to generate synthetic time series data for evolutionary scenarios with diverse phenotypic outcomes. Subsequently, we trained Physics-informed neural networks (PINNs) embedded in differential equations on the synthetic time series to reveal possible environments that select given phage traits and uncovered hidden interactions in the system [1].
Lastly, by using symbolic regression techniques, including Sparse Identification of Nonlinear Dynamical Systems (SINDy) and genetic algorithm-based methods, on the synthetic time series data, we derived governing differential equations that identified key environmental conditions and interaction pathways driving the evolution of specific phage traits in well-mixed and spatiotemporal microbial systems. These equations serve as a foundation for predicting the correct evolutionary experiment to select for the given phage traits.
This approach provides a scalable and adaptable framework for designing evolutionary experiments to select specific phage phenotypes. It highlights the power of integrating physics-informed neural networks, agent-based simulations, and symbolic regression techniques to offer new insights into the mechanisms underlying complex microbial ecosystems.
Reference:
[1] Grigorian, G., George, S.V. and Arridge, S., 2024. Learning Governing Equations of Unobserved States in Dynamical Systems. arXiv preprint arXiv:2404.18572.
–
Publication: H. Alam and D. Fusco, "A General Framework for Designing Evolutionary Experiments to Select Specific Phage Phenotypes Using Neural Networks and Symbolic Regression," manuscript in preparation (expected February 2026).
Presenters
-
Hassan Alam
- Univ of Cambridge