# Multi-physics modeling for ion homeostasis in multi-compartment plant cells using an energy function

**Authors:** Guillaume Mestdagh, Alexis De Angeli, Christophe Godin

PMC · DOI: 10.1371/journal.pcbi.1013474 · PLOS Computational Biology · 2025-11-20

## TL;DR

This paper introduces a new energy-based model to study how plant cells regulate water and ion transport through multiple compartments.

## Contribution

The paper presents a novel energy-based approach to unify chemical, electrical, and mechanical processes in multi-compartment plant cell modeling.

## Key findings

- The energy-based model systematically derives equations for ion and water transport in plant cells.
- The model explains the direction of system changes in response to perturbations during stoma opening.
- Numerical simulations reveal the role of hydrogen pumps in the transport process.

## Abstract

Plant cells control their volume by regulating the osmotic potential of their cytoplasm and vacuole. Water is attracted into the cell as the result of a cascade of solute exchanges between the cell subcompartments and the cell surroundings, which are governed by chemical, electrostatic and mechanical forces. Due to this multi-physics aspect and to couplings between volume changes and chemical effects, modeling these exchanges remains a challenge that has only been partially addressed. As interest for multi-compartment models grows in the plant cell community, this challenge calls for new modeling strategies. In this paper, we introduce an energy-based approach to couple chemical, electrical and mechanical processes taking place between several subcompartments of a plant cell. The contributions of all physical effects are gathered in an energy function, which allows us to derive the equations satisfied by each variable in a systematic way. We illustrate the properties of this modular, unified approach on the modeling of ion and water transport in a guard cell during stoma opening. We represent the stoma opening process as a quasi-static evolution driven by hydrogen pumps in the plasma and vacuolar membranes, and we show that the new formalism explains why the system varies in a particular direction in response to perturbations. Additional numerical simulations allow us to investigate the role of each hydrogen pump in this process. Altogether, we show that this energy-based approach highlights a hierarchy between the forces involved in the system, and to dissect the role of each physical effect in the complex behavior of the system.

Osmosis is a physical effect by which water is attracted into compartments with a high concentration of solute. Plant cells exploit osmosis to attract water into their subcellular compartments and increase their sizes. They use complex mechanisms, involving the circulation of several ion species between compartments, governed by chemical and physical phenomena of multiple natures. Due to the complexity of their interactions, these mechanisms are difficult to study experimentally, and require the development quantitative modeling approaches. In this paper, we propose a theoretical model whose goal is to show how these ions exchanges result in water finally flowing into the cell. Particular attention is paid to the competition between the various physical phenomena, their priorities and the way each of them influences the system.

## Full-text entities

- **Chemicals:** Water (MESH:D014867), hydrogen (MESH:D006859)

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12633951/full.md

## References

50 references — full list in the complete paper: https://tomesphere.com/paper/PMC12633951/full.md

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Source: https://tomesphere.com/paper/PMC12633951