Biology

Scientists create tool to track plant cell mutations across generations

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Researchers developed simSOMA, a computational simulator that models how somatic mutations accumulate and spread through plant tissues during growth. The simulator tracks mutations from their origin in stem cells through cell division, branching, and organ formation, predicting the complex patterns of variant allele frequencies observed in sequencing data. By allowing researchers to test different growth scenarios and sampling strategies, simSOMA helps interpret how developmental processes shape the distribution of somatic mutations across plant tissues.


This tool enables better understanding of how spontaneous mutations in plants can lead to commercially valuable bud sports in crops and contribute genetic variation that may be passed to future generations. The simulator will help researchers design more effective sequencing studies and distinguish between mutations arising from normal development versus those introduced by tissue sampling methods.


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Cell division Concept coming soon Stem cell Concept coming soon Somatic mutation Concept coming soon

⚠️ Preprint – Noch nicht peer-reviewed

Dieser Artikel wurde noch nicht von unabhängigen Experten begutachtet. Die Ergebnisse sind vorläufig und sollten mit Vorsicht interpretiert werden.

Plants accumulate somatic mutations during growth, and some of these mutations can spread from local cell lineages into branches, organs, or reproductive tissues. There is growing interest in these variants because they can underlie bud-sport traits in crops, contribute to within-organism somatic selection, and provide genetic variation that may be transmitted vegetatively or sexually to future generations. Recent genomic sequencing of bulk and layer-enriched plant tissues has shown that de novo somatic variants can generate complex variant allele-frequency (VAF) spectra. Interpreting these spectra requires understanding how mutations arising during mitotic cell division are filtered or amplified through shoot growth, branching, and organ formation. Because these processes interact across multiple scales, their combined effects are difficult to derive analytically. Here, we present simSOMA, a modular simulator that links rooted plant topologies to explicit cell-lineage dynamics. simSOMA models somatic mutation accumulation during stem-cell self-renewal in the shoot apical meristem, clonal expansion from the stem-cell niche to the meristem periphery, branch founding, and organ formation. Applying simSOMA across diverse growth scenarios revealed how individual processes can be isolated, varied, and combined to assess their effects on organ-level VAF spectra and among-organ variant sharing. The same simulated spectra can also be transformed to represent bulk or layer-enriched sampling and phased or unphased variant readouts, separating effects of developmental history from those introduced by tissue composition and allele counting. Because simSOMA is organized around modules with defined input-output interfaces, individual developmental components can be replaced or extended as new empirical information becomes available. This makes simSOMA a flexible tool for testing alternative models of somatic mosaicism in plants and for guiding the design and interpretation of VAF-based sequencing studies. The simulator is available at https://github.com/jlab-code/simSOMA.

Source: simSOMA: a cell-lineage based simulator of the somatic VAF spectrum in plants