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Antifungal Peptide P852 Effectively Controls <i>Fusarium oxysporum,</i> a Wilt-Causing Fungus, by Affecting the Glucose Metabolism and Amino Acid Metabolism as well as Damaging Mitochondrial Function

Hongji Wang, Lan Yao, Jie Chen, Zeran Ding, Xuan Ou, Chaowen Zhang, Jianjun Zhao, Yuzhu Han

2023Journal of Agricultural and Food Chemistry11 citationsDOI

Abstract

Fusarium oxysporum causes wilt disease, which causes huge economic losses to a wide range of agricultural cash crops. Antifungal peptide P852 is an effective biocide. However, the mechanism of direct inhibition of pathogenic fungus needs to be explored. The proteomics and transcriptomics results showed that P852 mainly affected intracellular pathways such as glucose metabolism, amino acid metabolism, and oxidoreductase activity in F. oxysporum . P852 disrupts the intracellular oxidative equilibrium in F. oxysporum, and transmission electron microscopy observed mitochondrial swelling, disruption of membrane structure, and leakage of contents. Decreased mitochondrial membrane potential, mitochondrial cytochrome c leakage, and reduced ATP production were also detected. These results suggest that P852 is able to simultaneously inhibit intracellular metabolism and disrupt the mitochondrial function of F. oxysporum, exerting its inhibitory effects in multiple pathways together. The present study provides some insights into the multitargeted mechanism of fungus inhibition of antifungal lipopeptide substances produced by Bacillus spp.

Topics & Concepts

Fusarium oxysporumBiochemistryMetabolismBiologyIntracellularMitochondrionMicrobiologyBotanyAntimicrobial Peptides and ActivitiesMedicinal Plants and NeuroprotectionMicrobial Natural Products and Biosynthesis
Antifungal Peptide P852 Effectively Controls <i>Fusarium oxysporum,</i> a Wilt-Causing Fungus, by Affecting the Glucose Metabolism and Amino Acid Metabolism as well as Damaging Mitochondrial Function | Litcius