Iron-clad defense: How microbes shield tomato crops from bacterial wilt

by

Editors' notes

This article has been reviewed according to Science X's editorial process and policies. Editors have highlighted the following attributes while ensuring the content's credibility:

fact-checked

peer-reviewed publication

proofread

Structural equation model linking siderophore production, siderophore-mediated interactions, and biomass with pathogen abundance and disease incidence (AUDPC) of plant bacterial wilt. Credit: Horticulture Research (2024). DOI: 10.1093/hr/uhae186

Ralstonia solanacearum is a soil-borne pathogen that devastates tomato and other Solanaceae crops globally. Traditional chemical controls have proven inadequate and environmentally damaging.

The plant root microbiome offers a potential solution by naturally inhibiting pathogens or competing for resources. However, limited understanding of these interactions, particularly iron competition, hinders effective field applications. Due to these challenges, it is essential to investigate mechanisms like siderophore-mediated iron competition more thoroughly.

A collaborative team from Nanjing Agricultural University, in partnership with international researchers, published a new study in Horticulture Research that reveals that Pseudomonas consortia employing siderophore-mediated competition suppress Ralstonia solanacearum more effectively than other mechanisms. This work pioneers a new strategy for utilizing microbial interactions to defend crops from bacterial wilt.

The researchers examined Pseudomonas strains known for their diverse siderophore production, revealing how these molecules disrupt the pathogen's access to iron. Through experiments under iron-limited and iron-rich conditions, they demonstrated that siderophores significantly enhanced pathogen inhibition.

A greenhouse assay validated these findings, showing reduced disease incidence in tomato plants inoculated with siderophore-producing consortia. Interestingly, the study found that while siderophores were highly effective, other antimicrobial metabolites had limited impact in iron-deficient environments. The researchers concluded that iron competition drives microbial community dynamics and is pivotal in disease suppression.

Dr. Tianjie Yang, senior researcher, emphasized, "Our findings spotlight the importance of iron-mediated microbial interactions. By engineering microbial consortia optimized for iron competition, we can sustainably control soil-borne diseases. This could revolutionize crop protection by reducing dependence on synthetic chemicals."

This research paves the way for microbiome-based agricultural innovations. Leveraging siderophore-producing consortia offers a natural, eco-friendly approach to managing plant diseases. As iron deficiency commonly occurs in soil, applying this strategy could benefit global crop production, boosting food security while mitigating environmental impact.

More information: Zhengying Shao et al, Siderophore interactions drive the ability of Pseudomonas spp. consortia to protect tomato against Ralstonia solanacearum, Horticulture Research (2024). DOI: 10.1093/hr/uhae186

Journal information: Horticulture Research

Provided by TranSpread