Browsing by Author "Dipanjali Bag"

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A review on phytotoxicity and defense mechanism of silver nanoparticles (AgNPs) on plants
(Springer Science and Business Media B.V., 2023) Sumit Kumar; Prahlad Masurkar; Bana Sravani; Dipanjali Bag; Kamal Ravi Sharma; Prashant Singh; Tulasi Korra; Mukesh Meena; Prashant Swapnil; Vishnu D. Rajput; Tatiana Minkina
Silver nanoparticles (AgNPs) are noteworthy used nanomaterials in a wide array of fields, particularly in the agricultural sector. Plants play a multifarious role in the ecosystem and provide a source of food for mankind. The responsibility of the scientific community is to recognize the deleterious impact of AgNPs (1–100 nm in size) on critical crop growth and development of plants, which is required for the assessment of environmental threats to plant, human, and animal health. The continued use of AgNPs in agriculture areas may have negative effects on plant biochemical and physiological responses. The current context focused mainly on AgNPs uptake, transport, and accumulation on crop plants and summarizes different levels of phytotoxicity of AgNPs on plant functions and focused on mechanisms of phytotoxicity employed by AgNPs. Moreover, some tolerance mechanisms and various survival strategies developed by plants under AgNPs toxicity are discussed. This background provides comprehensive information necessary to facilitate profound understanding of the toxic impacts of AgNPs on crop plants. © 2023, The Author(s), under exclusive licence to Springer Nature B.V.
Unraveling the role of antimicrobial peptides in plant resistance against phytopathogens
(Springer Nature, 2024) Sumit Kumar; Lopamudra Behera; Rajesh Kumari; Dipanjali Bag; Vanama Sowmya; Chetan Keswani; Tatiana Minkina; Ali Chenari Bouket; Pranab Dutta; Yasser Nehela; Rohini; Udai B. Singh; Aarti Bairwa; Harish; Abhishek Sahoo; Prashant Swapnil; Mukesh Meena
The current reports on phytopathogens multidrug resistance have become a significant issue for plant health and global food security. Antimicrobial peptides (AMPs) have recently gained generous attention as potential alternatives to prevent plant disease resistance because of their potent, multifarious antimicrobial activity. AMPs are low-weight protein molecules. Living organisms secrete a wide range of AMPs, with some synthesised by canonical gene expression, known as ribosomal AMPs, and non-ribosomal AMPs, synthesised by modular enzyme-generating systems. Plants produce an array of AMPs, yet they are still unknown to many infection processes of causal agents. Plant-derived AMPs have a wide range of structures and functions, and they induce an innate immune system in plants. The biologically active AMPs in plants mainly depend on direct and indirect interactions with membrane lipids. Transgenic plants have expressed several AMPs, the basis for the model of new synthetic analogues, to provide support against diseases. These peptides have shown significant ability to manage plant diseases and can provide an eco-friendly alternative to hazardous conventional methods. Here, we have a comprehensive study on AMPs to identify their role in plant pathogen stress suppression activities and their mode of action. This would surely facilitate a bottomless insight into AMPs' mode of action against pathogen infections. An improved understanding of the mechanism will facilitate the development of the next generation of antimicrobial peptides, potentially employing a multitargeted approach. © The Author(s) 2024.