# Learning metabolic dynamics from irregular observations by Bidirectional Time-Series State Transfer Network

**Authors:** Shaohua Xu, Ting Xu, Yuping Yang, Xin Chen

PMC · DOI: 10.1128/msystems.00697-24 · 2024-07-26

## TL;DR

This paper introduces a new neural network model that can accurately model microbial metabolic dynamics even when data is irregular or incomplete.

## Contribution

The novel Bidirectional Time-Series State Transfer Network (BTSTN) enables modeling of metabolic dynamics directly from irregular observations without preprocessing.

## Key findings

- BTSTN accurately reconstructs dynamic behaviors and predicts future trajectories from irregular data.
- The model shows enhanced robustness against missing measurements and noise compared to existing methods.
- BTSTN performs well on both ideal dynamic systems and real-world fermentation processes.

## Abstract

Modeling microbial metabolic dynamics is important for the rational optimization of both biosynthetic systems and industrial processes to facilitate green and efficient biomanufacturing. Classical approaches utilize explicit equation systems to represent metabolic networks, enabling the quantification of pathway fluxes to identify metabolic bottlenecks. However, these white-box models, despite their diverse applications, have limitations in simulating metabolic dynamics and are intrinsically inaccurate for industrial strains that lack information on network structures and kinetic parameters. On the other hand, black-box models do not rely on prior mechanistic knowledge of strains but are built upon observed time-series trajectories of biosynthetic systems in action. In practice, these observations are typically irregular, with discontinuously observed time points across multiple independent batches, each time point potentially containing missing measurements. Learning from such irregular data remains challenging for existing approaches. To address this issue, we present the Bidirectional Time-Series State Transfer Network (BTSTN) for modeling metabolic dynamics directly from irregular observations. Using evaluation data sets derived from both ideal dynamic systems and a real-world fermentation process, we demonstrate that BTSTN accurately reconstructs dynamic behaviors and predicts future trajectories. This approach exhibits enhanced robustness against missing measurements and noise, as compared to the state-of-the-art methods.

Industrial biosynthetic systems often involve strains with unclear genetic backgrounds, posing challenges in modeling their distinct metabolic dynamics. In such scenarios, white-box models, which commonly rely on inferred networks, are thereby of limited applicability and accuracy. In contrast, black-box models, such as statistical models and neural networks, are directly fitted or learned from observed time-series trajectories of biosynthetic systems in action. These methods typically assume regular observations without missing time points or measurements. If the observations are irregular, a pre-processing step becomes necessary to obtain a fully filled data set for subsequent model training, which, at the same time, inevitably introduces errors into the resulting models. BTSTN is a novel approach that natively learns from irregular observations. This distinctive feature makes it a unique addition to the current arsenal of technologies modeling metabolic dynamics.

## Full-text entities

- **Genes:** TetR [NCBI Gene 7324557]
- **Diseases:** ALL (MESH:D054198), F (OMIM:102510)
- **Chemicals:** succinate (MESH:D019802), BTSTN (-)
- **Species:** Escherichia coli (E. coli, species) [taxon 562], Saccharomyces cerevisiae (baker's yeast, species) [taxon 4932], Streptomyces (genus) [taxon 1883]
- **Cell lines:** S2 — Drosophila melanogaster (Fruit fly), Spontaneously immortalized cell line (CVCL_Z232)

## Figures

50 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11334518/full.md

---
Source: https://tomesphere.com/paper/PMC11334518