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Full Description
This new 3-volume set provides a comprehensive understanding of the mechanisms that mediate biosynthesis, accumulation, and degradation of plant metabolites so as to employ novel strategies to improve crop production and enhance abiotic stress tolerance in plants. Abiotic stresses such as drought, high salt, cold, heat, UV radiation, heavy metal pollution, etc., are increasingly responsible for restricting plant growth and agricultural production and are becoming more alarming due to threats from global climate change. To combat these threats, it is imperative to study the underlying mechanisms of stress tolerance from diverse metabolites and the biosynthesis pathways for metabolite production to maintain osmotic balance under diverse environmental stresses. Biology and Biotechnology of Environmental Stress Tolerance in Plants provides that understanding.
Volume 1: Secondary Metabolites in Environmental Stress Tolerance focuses exclusively on the diverse secondary metabolites that play a major role in the adaptation of plants to the environment and in overcoming stress conditions as well as their implications in enhancing tolerance mechanisms. The chapters in this section review and integrate the currently available information on the protective role rendered by a wide array of antioxidative secondary metabolites and their regulation during diverse environmental stress.
Volume 2: Trace Elements in Environmental Stress Tolerance throws light on the different inorganic trace elements, including metal nanoparticles, that help to deal with various environmental stresses. While these elements at high level create considerable phytotoxicity and halt metabolic and enzymatic activity, they also promote growth and development in limited quantity, so that they have significant potential in revamping plant morphology and physiology under stressed conditions. Hence, optimum concentration management of these elements can help to mitigate world hunger and contribute toward sustainable agriculture and food security under challenging environments.
Volume 3: Sustainable Approaches for Enhancing Environmental Stress Tolerance focuses on the agronomic and biochemical approaches as well as biotechnological and high-throughput technologies, including the prospects of genetic engineering, epigenetics and the latest CRISPR/Cas technology, in generating stress-tolerant plants. The volume provides a clear road map for the implementation of techniques for improving abiotic stress tolerance in plants for better sustenance.
Key features:
Provides an advanced understanding of the mechanisms of action of secondary metabolites and trace elements in environmental stress tolerance as well as the different agronomic and biotechnological methods that enhances stress tolerance
Looks at the overall metabolic pathways and genetic engineering, giving a holistic view of plant-level studies of diverse abiotic stresses affecting different metabolic pathways
Provides the groundwork to help researchers in designing future programs for identifying novel genes and proteins and targeting proper pathways to develop climate-resilient plants
Altogether the three-volume Biology and Biotechnology of Environmental Stress Tolerance in Plants will enhance our understanding of plant responses to environmental stresses and enable implementation of programs and practices that can help us to develop climate-resilient plants with better performance for better yield and quality.
Contents
VOLUME 1: SECONDARY METABOLITES IN ENVIRONMENTAL STRESS TOLERANCE Part 1: Pathways for Secondary Metabolite Production 1. Plant Secondary Metabolites and Environmental Stress: An Overview 2. Involvement of Phenylpropanoid Pathway and Shikimic Acid Pathway in Environmental Stress Response 3. Terpenoid Production through Mevalonate and Methylerythritol Phosphate Pathway and Regulation of Environmental Stress Tolerance Part 2: Individual Secondary Metabolites in Tolerance 4. Role of Diverse Classes of Terpenoids in Tolerance against Different Environmental Stresses 5. Terpenoids in Plant Tolerance against Different Environmental Stresses 6. Role of Anthocyanin in Plants to Survive against Environmental Stresses 7. Role of Carotenoids in Tolerance against Different Environmental Stresses 8. Involvement of Chalcones and Coumarins in Environmental Stress Tolerance 9. Role of Phenolic Acids and Flavonoids in the Mitigation of Environmental Stress in Plants Part 3: Application and Analysis of Secondary Metabolites 10. Seedling and Seed Priming in Regulating Secondary Metabolite Level for Stress Tolerance 11. Seed Priming and Seedling Pre-Treatment in Regulating Secondary Metabolism for Stress Tolerance 12. Tools and Approaches for Assessing Stress-Responsive Secondary Metabolites to Design Climate-Smart Crops VOLUME 2: TRACE ELEMENTS IN ENVIRONMENTAL STRESS TOLERANCE Part 1: Trace Elements in Sustaining Plant Growth 1. Trace Elements in Mitigating Environmental Stress: An Overview 2. Trace Elements and Their Role in Abiotic Stresses 3. Exogenous Application of Trace Elements and Their Uptake by Plants to Mediate Abiotic Stress Tolerance Part 2: Individual Trace Elements in Tolerance 4. Role of Iron and Manganese in Tolerance against Different Environmental Stress 5. Role of Zinc in Tolerance against Different Environmental Stresses 6. Role of Silicon in Tolerance against Different Environmental Stresses 7. Role of Selenium in Tolerance against Different Environmental Stresses 8. Role of Nickel as a Potent Environmental Stress Reliever in Plants 9. Role of Cobalt in Plant Growth and Tolerance against Different Environmental Stresses 10. Role of Molybdenum in Tolerance against Different Environmental Stresses 11. Role of Copper in Tolerance against Different Environmental Stresses 12. Role of Sulfur in Plant Tolerance to Environmental Stresses 13. Role of Chloride and Organic Acid Anions in Environmental Stress Tolerance 14. Role of Sulfur in Protection against Major Environmental Stress in Plants Part 3: Nanoparticles in Stress Tolerance 15. Application of Nanomaterial-Based Technology in Stress Management of Plants 16. Role of Nanoparticles in Tolerance against Different Environmental Stresses 17. Nanotechnology and Use of Nanoparticles in Developing Environmental Stress Tolerant Plants VOLUME 3: SUSTAINABLE APPROACHES IN ENHANCING ENVIRONMENTAL STRESS TOLERANCE Part 1: Microorganism Application and Stress Tolerance 1. Soil Microorganisms and Nematodes for Bioremediation and Amelioration of Polluted Soils 2. Rhizospheric Microbial Inoculation in Developing Stress Tolerance 3. Role of Endophytes, Plant Growth Promoting Rhizobacteria, and Arbuscular Mycorrhizal Fungi in Stress Tolerance Part 2: Priming and Genetic Engineering 4. Role of Hydropriming and Magneto Priming in Developing Stress Tolerance 5. Magneto Priming: A Novel Technique towards Improved Seed Germinability and Stress Responses: From Basics to Contemporary Advancements 6. Plant Breeding Approaches in Developing Stress Tolerance 7. Towards Engineering Smart Transcription Factors for Enhanced Abiotic Stress Tolerance in Plants 8. Genetics and Microarray in Environmental Stress Response 9. Small RNAs: The Big Players in Developing Salt-Resistant Plants Part 3: Epigenetics and Omics Approaches 10. Genome-Wide Association Studies and Next-Generation Sequencing in Plant Response to Environmental Stress 11. CRISPR/Cas and Its Potential as an Effective Tool in Understanding Environmental Stress Response 12. Epigenetics: The Molecular Tool in Understanding Abiotic Stress Response in Plants 13. Advances in Proteomics Research in Environmental Stress Response in Plants 14. Advances in Metabolomics Research in Environmental Stress Response in Plants
