This study emphasizes the production of eco-friendly silver nanoparticles from a medicinal plant extract of
Morinda lucida (M. lucida)
and investigated its antioxidant and antimicrobial activity. Phytochemical screening of
M. lucida (ML)
leave extract was carried out and observed to contain some fundamental phyto-reducing agents such as reducing sugar, proteins, and alkaloids. The green synthesized AgNPs (ML-AgNPs) were characterized by UV–vis spectroscopy, Fourier transform infrared spectroscopy (FTIR), transmission emission microscopy (TEM), scanning electron microscopy (SEM), X-ray diffraction (XRD), and Energy dispersive X-ray analysis (EDX). Thermo gravimetric analysis (TGA) was performed on the synthesized ML-capped AgNPs to determine the thermal stability and the formation of the green synthesized AgNPs. The formation of AgNPs was confirmed by the UV–vis absorption spectra, which showed an absorption band at 420 nm. The morphology of ML extract-mediated AgNPs was mostly spherical and rough-edged crystallite nanostructures, with an average particle size of 11 nm. The FTIR analyses revealed distinctive functional groups which were directly involved in the synthesis and stability of AgNPs. The crystallite size was 8.79 nm, with four intense peaks at 2
θ
angles of 38°, 44°, 64°, and 77°. At an energy level of 3.4 keV, a significant signal was observed indicating the production of thermally stable and pure crystallite AgNPs. The antioxidant property of green synthesized ML-AgNPs was determined to be 40% higher than that of crude
M. lucida
leaf extract. The ability of green synthesized ML-AgNPs to scavenge free radicals also increased in the order of OH
−
< NO < H
2
O
2
. The ML-AgNPs have strong activities with a maximum against
P. vulgaris
and a minimum with
E. faecalis.
Cell and sub‐cellular anatomical adjustments are adaptations utilized by plants to tolerate abiotic stress. Both melatonin and Morinda lucida‐silver nanoparticles (ML‐AgNPs) are recognized as bio‐stimulants. The study examined the morphological changes and adaptive characteristics of these bio‐stimulants under water‐stress Eugenia uniflora. Twenty‐four hours was spent priming the seeds with melatonin (0.06 mg/L), ML‐AgNPs (0.06 mg/L), and a mixture (1:1) of the two. The seeds were sown and subjected to water stress for 7 days. The leaves, stems, and roots of water‐stressed E. uniflora were sectioned, dried, and examined using a microscope. Drought stress led to the production of non‐glandular trichomes on the abaxial and the transformation of paracytic stomata into diacytic stomata. During water stress, melatonin enlarges intercellular gaps and stomata, increases sponge and palisade parenchyma, and thickens epidermis (stem and root) and fibers. The ML‐AgNPs diminished the size of mesophyll, intercellular gaps, stomata, and stem fiber. The ML‐AgNPs increased the size of bulliform cells and activated the mechanical resistance features of sclerophyllous leaves (thick‐celled epidermis and sclerieds) and ray parenchyma (root and stem). Equally, Melatonin and ML‐AgNPs increased stem and root anatomical characteristics (xylem, bark, pith, cortex, epidermis, and vascular bundles). Stomata of E. uniflora are susceptible to alterations and undergo cell division into two new stomata (stomatogensis) in response to varying conditions (melatonin and ML‐AgNPs). Melatonin adopted a strategy for maintaining a high plant water status, possibly by osmoregulation, whereas E. uniflora primed with ML‐AgNPs survived by minimizing transpirational water loss through morphological changes.
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