# Multi-omics insights into plant-microbe dysbiosis caused by cyanobacterial bloom-affected water

**Authors:** Minsoo Jeong, Soeun Park, Seungjin Jeong, Surye Park, Sohyun Yeo, Bomi Ryu, Jae-Ho Shin, Seungjun Lee

PMC · DOI: 10.1016/j.crmicr.2025.100500 · 2025-10-23

## TL;DR

Cyanobacteria-contaminated water harms lettuce growth by disrupting energy metabolism and increasing harmful microbes.

## Contribution

This study reveals how cyanobacterial bloom-affected water causes plant-microbe dysbiosis through multi-omics insights.

## Key findings

- Cyanobacteria exposure inhibited lettuce growth and caused microcystin accumulation in edible tissues.
- Energy metabolism genes were downregulated, and antioxidant metabolites decreased in treated lettuce.
- Pathogenic Pseudomonas species increased 2.3-fold in cyanobacteria-exposed lettuce.

## Abstract

•Toxic cyanobacteria-contaminated irrigation water inhibited lettuce growth and development.•Genes related to energy metabolism were downregulated in response to cyanobacteria exposure.•Anti-inflammatory and antioxidant metabolite levels decreased in cyanobacteria-treated lettuce.•Pathogenic Pseudomonas species increased 2.3-fold in lettuce exposed to toxic cyanobacteria

Toxic cyanobacteria-contaminated irrigation water inhibited lettuce growth and development.

Genes related to energy metabolism were downregulated in response to cyanobacteria exposure.

Anti-inflammatory and antioxidant metabolite levels decreased in cyanobacteria-treated lettuce.

Pathogenic Pseudomonas species increased 2.3-fold in lettuce exposed to toxic cyanobacteria

The use of untreated, cyanobacterial bloom–affected river water as a readily available source for crop production is a realistic scenario in many regions, yet its systemic impact on crop health remains poorly defined. Here, we investigate the multifaceted effects of this practice by cultivating lettuce (Lactuca sativa) with bloom-season water from the eutrophic Nakdong River and comparing it to lettuce grown in a nutrient-optimized hydroponic solution. We found that exposure to bloom-affected water severely inhibited plant growth and led to the accumulation of microcystins in edible tissues, with estimated daily intakes exceeding WHO safety thresholds. Multi-omics analyses revealed that this phenotype was driven by a synergistic failure of internal and external support systems: key mitochondrial genes for energy production were downregulated, protective antioxidant flavonoids were depleted, and the aquatic microbiome shifted to a dysbiotic state that favored stress-tolerant taxa while reducing beneficial ones. Together, these results establish how bloom-affected water initiates a vicious cycle of physiological stress and microbial dysbiosis that undermines crop health. This study provides an integrative framework for assessing risks in real-world hydroponic systems and for guiding future investigations into more complex soil-based agriculture.

Image, graphical abstract

## Linked entities

- **Species:** Lactuca sativa (taxon 4236), Pseudomonas (taxon 286)

## Full-text entities

- **Chemicals:** microcystins (MESH:D052998), flavonoids (MESH:D005419)
- **Species:** Lactuca sativa (cultivated lettuce, species) [taxon 4236]

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12615344/full.md

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Source: https://tomesphere.com/paper/PMC12615344