Salinity Stress in Wheat (Triticum aestivum L.) in the Changing Climate: Adaptation and Management Strategies
Copyright policy )Salinity Stress in Wheat (Triticum aestivum L.) in the Changing Climate: Adaptation and Management Strategies
Wheat constitutes pivotal position for ensuring food and nutritional security; however, rapidly rising soil and water salinity pose a serious threat to its production globally. Salinity stress negatively affects the growth and development of wheat leading to diminished grain yield and quality. Wheat plants utilize a range of physiological biochemical and molecular mechanisms to adapt under salinity stress at the cell, tissue as well as whole plant levels to optimize the growth, and yield by off-setting the adverse effects of saline environment. Recently, various adaptation and management strategies have been developed to reduce the deleterious effects of salinity stress to maximize the production and nutritional quality of wheat. This review emphasizes and synthesizes the deleterious effects of salinity stress on wheat yield and quality along with highlighting the adaptation and mitigation strategies for sustainable wheat production to ensure food security of skyrocketing population under changing climate.
- University of Ruhuna Sri Lanka
- Slovak University of Agriculture Slovakia
- Kafrelsheikh University Egypt
- Czech University of Life Sciences Prague
- Uludağ University Turkey
Impacts of Elevated CO2 and Ozone on Plant Physiology, Salinity, Soil salinity, physiological and biochemical mechanisms, Population, Plant Science, Yield (engineering), Environmental science, SB1-1110, Agricultural and Biological Sciences, wheat, Climate change, Plant Growth, Molecular Responses to Abiotic Stress in Plants, Biology, salinity stress, antioxidant defense, stress tolerance, Adaptation (eye), Ecology, S, Plant culture, Life Sciences, Agriculture, Food security, Agronomy, Materials science, Environmental health, Plant Responses to Flooding Stress, FOS: Biological sciences, Metallurgy, Medicine, Neuroscience
Impacts of Elevated CO2 and Ozone on Plant Physiology, Salinity, Soil salinity, physiological and biochemical mechanisms, Population, Plant Science, Yield (engineering), Environmental science, SB1-1110, Agricultural and Biological Sciences, wheat, Climate change, Plant Growth, Molecular Responses to Abiotic Stress in Plants, Biology, salinity stress, antioxidant defense, stress tolerance, Adaptation (eye), Ecology, S, Plant culture, Life Sciences, Agriculture, Food security, Agronomy, Materials science, Environmental health, Plant Responses to Flooding Stress, FOS: Biological sciences, Metallurgy, Medicine, Neuroscience
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