Effect of Green Biosynthesized Silver Nanoparticles Using Cleome amblyocarpa on Controlling Chickpea Wilt

ElSharawy, Ahmed A.; Ibrahim, Mahmoud S.S.; Mossa, Monga I.

doi:10.21608/ejp.2023.186891.1081

Effect of Green Biosynthesized Silver Nanoparticles Using Cleome amblyocarpa on Controlling Chickpea Wilt

Document Type : Original Article

Authors

¹ Plant Pathology Lab., Plant Production Department., Faculty of Environmental Agricultural Science, Arish University, Egypt

² Physics Department, Faculty of Science, Arish University, Arish, Egypt.

³ Botany Department Faculty of science, Arish University, Egypt.

10.21608/ejp.2023.186891.1081

Abstract

The antifungal activity of green synthesized silver nanoparticles (AgNPs) from Cleome amblyocarpa was investigated against the phytopathogenic fungus Fusarium oxysporum (MW485609) the cause of chickpea wilt. Experimental results showed that the growth of F. oxysporum started to reach 50 % inhibition at 80 𝜇g/mL of AgNPs and also with 150 𝜇g/mL plant extract. The highest reduction % on the mycelial growth was 60.4 ± 0.00 and 67.4±1.16mm with plant extract and green synthesized nanoparticles, respectively. Data also revealed that the most effective concentration of green AgNPs solution was, 200 µl/mL, which showed 5.18 % and 9.79 % early and late wilt incidence. On the other hand, early and late wilt incidence recorded 11.24 % and 16 % due to plant extract. Meanwhile, plant survival rates were 85.03 % and 72.76 %, respectively, whereas the untreated control plants recorded only 4.85 % survivals. Images proved that the green synthesized silver nanoparticles affected the morphology of fungal hyphae grown on media supplemented with (AgNPs) solution and nanoparticles appeared in fungal cell walls compared with the effect of plant extract and with fungal hypha of control plates. Moreover, observations with TEM and SEM revealed that synthesized nanoparticles damaged fungal hyphae, causing the deformation of cell membranes and inhibition of the normal budding process. The solution of AgNPs illustrates good stability at -19.8 mV at an area of 100 %, a width of 6.75 mV. The size of AgNPs ranged from 6.06 to 40.9 nm; Mean = 20.088 nm, Dev (rms) = 7.2 nm. This research demonstrates that (AgNPs) can be employed as a safe and environmentally acceptable alternative in controlling pathogenic fungi, and limits dependence on fungicides and avoids the development of fungicide-resistant phytopathogenic generations. The green synthesis of nanoparticles with the help of C. amblyocarpa was considered a practicable and environmentally friendly way.

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