Abstract
Chitosan nanoparticles (ChiNPs) are a potentially effective means for controlling numerous plant diseases. This study firstly describes the antiviral capabilities of ChiNPs to control plant viral diseases compared to its bulk form. Bean yellow mosaic virus (BYMV) was used as a model plant virus affecting faba bean plants and many other legumes. The antiviral effectiveness of ChiNPs and chitosan were evaluated as a curative application method, using six dosage rates (50, 100, 200, 250, 300 and 400 mg/L). Results indicated that ChiNPs curatively applied 48 h post virus inoculation entirely inhibit the disease infectivity and viral accumulation content at 300 mg/L and 400 mg/L. The virus titre was greatly alleviated within the plant tissues by 7.71% up to100% depending on ChiNP dosage rates. However, chitosan used in its bulk-based material form revealed a relatively low to an intermediate reduction in virus infectivity by 6.67% up to 48.86%. Interestingly, ChiNPs affect the virus particle’s integrity by producing defective and incomplete BYMV viral particles, defeating their replication and accumulation content within the plant tissues. Simultaneously, ChiNP applications were appreciably shown to promote the pathogenesis-related (PR-1) gene and other defence-related factors. The mRNA of the PR-1 gene was markedly accumulated in treated plants, reaching its maximum at 400 mg/L with 16.22-fold relative expression change over the untreated control. Further, the total phenol dynamic curve was remarkably promoted for 30 days in response to ChiNP application, as compared to the untreated control. Our results provide the first report that chitosan-based nanomaterials have a superior effect in controlling plant viruses as an antiviral curing agent, suggesting that they may feasibly be involved in viral disease management strategies under field conditions without serious health concerns and environmental costs.Significance: Our findings show that chitosan nanoparticles have a powerful curing antiviral activity against BYMV disease. These findings open the door for the use of eco-friendly nano-based tools in controlling numerous plant viruses. The use of eco-friendly nano-based materials could result in a successful integrative control strategy for plant viruses under field conditions, negating the need for the conventional measure used to control most of the insect-transmitted plant viruses, that is insecticide application against vector insects.
Highlights
Plant viruses are destructive diseases that cause serious concerns for the agroecosystem and global food security due to their ability to infect many plant species that are grown for both food and feed production.[1]
The biologically isolated source produced mosaic symptoms typical of Bean yellow mosaic virus (BYMV) disease and similar to those observed in the field (Figure 1a)
BYMV isolate was confirmed by DAS-ELISA in mechanically inoculated plants and all tested samples were positive for BYMV
Summary
Plant viruses are destructive diseases that cause serious concerns for the agroecosystem and global food security due to their ability to infect many plant species that are grown for both food and feed production.[1] Faba bean (Vicia faba L.) is a legume crop cultivated mainly for its edible seeds. Due to their high protein content, faba beans are widely used as a cheap and high-quality protein source for poor consumers in many developing countries.[2] Bean yellow mosaic virus (BYMV) belongs to the Potyvirus genus (Family: Potyviridiae) and is a devastating viral disease for many crop legumes and ornamental plants throughout the world.[3] BYMV disease poses a significant threat for faba bean production, with losses of 30–50%.4. New strategic technologies are urgently needed to avoid pesticide treadmills
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