# Decoding living systems: Reassessing crop model frontiers via biological dynamics and optimized phenotype

**Authors:** Edgar S. Correa, Paulo Eduardo Teodoro, Paulo Eduardo Teodoro, Paulo Eduardo Teodoro, Paulo Eduardo Teodoro

PMC · DOI: 10.1371/journal.pone.0343530 · 2026-03-11

## TL;DR

This paper introduces a framework to model and optimize crop performance by integrating biological processes and AI, revealing strategies for yield under varying water conditions.

## Contribution

A novel inverse engineering framework combining sensitivity analysis, genetic algorithms, and similarity analysis to optimize crop phenotypes.

## Key findings

- Eight genetic coefficients were identified as key yield drivers with consistent rankings.
- Two adaptive strategies were found: extended growth under high water and shortened cycles under water deficit.
- WAB56−50 and DKAP2 were identified as top breeding candidates with a 22–30% genetic gap to computational optima.

## Abstract

Modeling and optimizing phenotypic performance of biological systems demands understanding how physiological processes mediate genotype-by-environment interactions. While AI-driven approaches achieve predictive accuracy, they often function as black boxes that obscure biological causality. Process-based models address this limitation through explicit mechanistic representation, enabling both quantitative optimization and biological interpretation. This study contributes an inverse engineering framework with three integrated layers: sensitivity analysis validating biological coherence, genetic algorithm exploring virtual phenotypes to identify adaptive strategies, and similarity analysis quantifying routes from computational optima to field-validated cultivars. Sensitivity analysis identified eight genetic-based coefficients governing yield with robust rankings (95% CI width = 0.04). The genetic algorithm explored 5,364 virtual cultivars across 40 generations, revealing two strategies: extended growth (116 days) achieving 4,837 kg/ha under higher water availability (815 mm, field capacity 0.30), and shortened cycles (100–103 days) maintaining high efficiency (HI: 0.55–0.58) under water deficit (540 mm, field capacity 0.23)—covering 89% of the cultivation area. Similarity analysis against 21 field-validated cultivars identified WAB56−50 (70.7%) and DKAP2 (67.2%) as breeding candidates, quantifying a 22–30% genetic gap between current germplasm and computational optima. The framework, built upon 3 years of field characterization, compressed the evaluation and selection cycle, enabling adaptation across regional precipitation gradients identified through GMM-based classification. The principles demonstrated here extend across biological scales—from organismal phenotyping to cellular systems where biological dynamics can be modeled and traits measured.

## Full-text entities

- **Diseases:** drought (MESH:C536747), HI (MESH:C566784), Spikelet sterility (MESH:D007246), VPD (MESH:D009461), WUE (MESH:D000069578), CERES-Rice (MESH:D007922)
- **Chemicals:** PONE-D-25-26754R2 (-), Water (MESH:D014867), carbon (MESH:D002244)
- **Species:** Oryza sativa (Asian cultivated rice, species) [taxon 4530]

## Figures

50 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12978445/full.md

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Source: https://tomesphere.com/paper/PMC12978445