AI Article Synopsis
- Mungbean is a crucial source of plant protein and a valuable export crop, but many varieties are susceptible to a soil-borne pathogen that causes Fusarium wilt, leading to significant yield losses.
- A study was conducted on 23 diverse mungbean accessions in Australia to assess their development and productivity under both disease-infected and healthy conditions, revealing substantial genetic variation in various traits.
- The research identified eight tolerant genotypes, highlighting their unique growth behaviors and traits, which could be used for breeding programs aimed at improving resilience against disease while sustaining yield.
Article Abstract
Mungbean is an important source of plant protein for consumers and a high-value export crop for growers across Asia, Australia and Africa. However, many commercial cultivars are highly vulnerable to biotic stresses, which rapidly reduce yield within the season. is a soil-borne pathogen that is a growing concern for mungbean growers globally. This pathogen causes Fusarium wilt by infecting the root system of the plant resulting in devastating yield reductions. To understand the impact of on mungbean development and productivity and to identify tolerant genotypes, a panel of 23 diverse accessions was studied. Field trials conducted in 2016 and 2021 in Warwick, Queensland, Australia under rainfed conditions investigated the variation in phenology, canopy and yield component traits under disease and disease-free conditions. Analyses revealed a high degree of genetic variation for all traits. By comparing the performance of these traits across these two environments, we identified key traits that underpin yield under disease and disease-free conditions. Aboveground biomass components at 50 % flowering were identified as significant drivers of yield development under disease-free conditions and when impacted by resulted in up to 96 % yield reduction. Additionally, eight genotypes were identified to be tolerant to . These genotypes were found to display differing phenological and morphological behaviours, thereby demonstrating the potential to breed tolerant lines with a range of diverse trait variations. The identification of tolerant genotypes that sustain yield under disease pressure may be exploited in crop improvement programs.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11034375 | PMC |
| http://dx.doi.org/10.1093/aobpla/plae021 | DOI Listing |
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