Abstract
Biogenic copper nanoparticles (Cu NPs) were synthesized using the aqueous crude extract of mangrove leaves, Avicennia marina (CE). GC-MS metabolite profiling of CE showed that their carbohydrates are mainly composed of D-mannose (29.21%), D-fructose, (18.51%), L-sorbose (12.91%), D-galactose (5.47%) and D-Talose (5.21%). Ultra-fine nanoparticles of 11.60 ±4.65 nm comprising Cu2O and Cu(OH)2 species were obtained with a carbohydrate and phenolic content of 35.6±3.2% and 3.13±0.05 mgGA/g, respectively. The impact of the biogenic Cu NPs on wheat seedling growth was dose-dependent. Upon treatment with 0.06 mg/mL of Cu NPs, the growth was promoted by 172.78 ± 23.11 and 215.94 ± 37.76% for wheat root and shoot, respectively. However, the lowest relative growth % of 81.94 ± 11.70 and 72.46 ± 18.78% were recorded for wheat root and shoot, respectively when applying 0.43 mg/mL of Cu NPs. At this concentration, peroxidase activity (POX) of the germinated wheat seeds also decreased, while ascorbic acid oxidase (AAO) and polyphenol oxidase (PPO) activities increased. Higher uptake of copper was observed in the root relative to the shoot implying the accumulation of the nanoparticles in the former. The uptake was also higher than that of the commercial Cu NPs, which showed an insignificant effect on the seedling growth. By treating the wheat leaves in foliar application with 0.06 mg/mL of Cu NPs, their contents of Chlorophyll a, Chlorophyll b, and total chlorophyll were enhanced after 21 days of application. Meanwhile, the high concentration (0.43 mg/mL) of Cu NPs was the most effective in reducing the leaf content of chlorophyll (a, b, and total) after the same time of application. The findings of this study manifest the potential of utilizing controlled doses of the prepared biogenic Cu NPs for inhibition or stimulation of seedling growth.
Highlights
Marine plants have been recently the subject of a myriad of studies due to their diverse biological activities
Role of biogenic copper nanoparticles from Avicennia marina leaves in seed germination seedlings enhanced their growth, while treating the seedlings with high concentrations of the nanoparticles suppressed the seedling growth relative to the control
The chlorophyll content was either enhanced or inhibited depending on the concentration of Cu NPs which was applied on the wheat leaves (21-days old)
Summary
Marine plants have been recently the subject of a myriad of studies due to their diverse biological activities. Several biological activities have been reported for mangroves such as antimicrobial [4], antioxidant [5], antidiabetic [6], antibacterial [7] and anticancer activities [8], and these were owed to its composition, which constitutes phytochemicals as alkaloids, phenolic compounds, steroids, terpenoids, glucosides and flavonoids together with polysaccharides [9,10,11] In addition to their bioactivities, the mangrove extracts can be utilized as reducing agents for the synthesis of metal/metal oxide nanoparticles (NPs) that are bioactive, probably due to their unique physicochemical properties that are related to their high surface area, high reactivity, tunable pore size, and particle morphology. Along with their role in bioreduction, the extracts form a stabilizing layer around the NPs, preventing them from agglomeration and contributing to their bioactivity through its active functional groups
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