Kanagaraj Muthu-Pandian Chanthini, Ganesh-Subbaraja Pavithra, Ponnusamy Murugan, Pauldurai Malarvizhi, Arulsoosairaj Deva-Andrews, Ramakrishnan Ramasubramanian, Narayanan Thulasi-Raman, Rajakrishnan Rajagopal, Sengottayan Senthil-Nathan, Guilherme Malafaia
Environmental research 2024 Oct 15Soil deterioration is a major cause of poor agricultural productivity, necessitating sufficient nutrient inputs like fertilizers and amendments for sustainable use. As one such strategy, the current study evaluates the potential of Sargassum wightii, a brown seaweed extract, as an osmopriming agent to improve seed germination, early establishment, and competent seedling performances in acidic soil. The elemental makeup of seaweed extract (BS) showed that it included major plant macro (Potassium, Nitrogen and Phosphorous), as well as micronutrients (Magnesium and Iron) and trace elements (Zinc, Copper, and Molybdenum). While seed germination was impacted by H+ ion toxicity, seeds primed with BS emerged earlier and showed a higher germination percentage (98.2%) and energy (92.4%). BS treatments enhanced seedling growth by 63% and had a positive effect on root growth (68.2%) as well as increases in root surface area (10%) and volume (67.01%). Stressed seedlings had 76.39% and 63.2% less carotenoid and chlorophyll, respectively. In seedlings treated with BS, an increase in protein and Total Soluble Sugars content of 14.56 and 7.19%, respectively, was seen. Fourier Transform-Infra Red analysis of postharvest soil indicated improved soil health with absorbance corresponding to enhanced soil water holding capacity and organic matter. Increased abscisic acid synthesis rate and associated antioxidant enzyme system (Malondialdehyde, Glutathione peroxidases and ascorbate peroxidase) activation, along with enhanced H+ adenosine triphosphate-ase and glutathione activities, help ameliorate and deport H+ ions from cells, scavenge Reactive Oxygen Species, thus protecting cells from injury. Seaweed extract successfully reduced H+-induced ion toxicities in rice by promoting their germination, physiological, metabolically, and growth parameters that could ultimately increase their productivity and yield in a sustainable and environmentally friendly manner. Copyright © 2024 Elsevier Inc. All rights reserved.
Kanagaraj Muthu-Pandian Chanthini, Ganesh-Subbaraja Pavithra, Ponnusamy Murugan, Pauldurai Malarvizhi, Arulsoosairaj Deva-Andrews, Ramakrishnan Ramasubramanian, Narayanan Thulasi-Raman, Rajakrishnan Rajagopal, Sengottayan Senthil-Nathan, Guilherme Malafaia. Enhancement of root abscisic acid mediated osmotic regulation by macroalgal compounds promotes adaptability of rice (Oryza sativa L.) in response to progressive metal ion mediated environmental stress. Environmental research. 2024 Oct 15;259:119485
PMID: 38917933
View Full Text