Effect of tropolone on gray mold rot in harvested fruit and its involved mechanism

Botrytis cinerea is one of the most devastating pathogen responsible for postharvest decay of fresh fruits and vegetables. However, traditional fungicide application is inclined to develop resistance strains, complicating the control of gray mold. Hence, there is an urgent need for exploiting new an...

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Bibliographic Details
Published in:Postharvest biology and technology 2025-01, Vol.219, p.113255, Article 113255
Main Authors: Chen, Daoguo, Chen, Yongxian, Chen, Tong, Chen, Yong, Xu, Yong, Blennow, Andreas, Li, Boqiang, Tian, Shiping
Format: Article
Language:English
Subjects:
antifungal properties
Botrytis cinerea
cell membranes
corn starch
disease severity
Fruit
fruits
fungicide application
gene expression
gray mold
mycelium
nanoparticles
pathogens
Postharvest control
postharvest diseases
protective effect
spore germination
spores
Starch nanoparticles
Tropolone
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Summary:Botrytis cinerea is one of the most devastating pathogen responsible for postharvest decay of fresh fruits and vegetables. However, traditional fungicide application is inclined to develop resistance strains, complicating the control of gray mold. Hence, there is an urgent need for exploiting new antifungal active substances and enhancing their antifungal activity in an environmentally friendly manner. In this study, tropolone was demonstrated efficacy in inhibiting B. cinerea mycelial growth at relatively low (40 mg L−1) tropolone concentrations and spore germination at even lower (10 mg L−1) tropolone concentrations. The antifungal mechanisms were linked to the disruption of spore germination-related gene expression rather than directly killing B. cinerea through cell membrane disruption. The inhibition of spore germination hindered the penetration of B. cinerea into host cells, thereby reducing disease severity in harvested apples and strawberries. To increase the protective effect of tropolone, we prepared small-sized maize starch nanoparticles loaded with tropolone and confirmed an enhanced antifungal effect. This study provides a theoretical foundation for the application of small-sized maize starch nanoparticles to increase antifungal effect and reduce fungicide application in postharvest disease control. •Tropolone suppressed spore germination of Botrytis cinerea.•Tropolone modulated the MAPK cascade and the cAMP-dependent signaling pathway.•Tropolone mitigated the incidence and severity of gray mold in fruit.•Maize starch nanoparticles (MS-NPs) enhanced the antifungal activity of tropolone.
ISSN:0925-5214
DOI:10.1016/j.postharvbio.2024.113255