Global climate change and plant stress management / / edited by Mohammad Wahid Ansari, Anil Kumar Singh and Narendra Tuteja
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| Titolo: |
Global climate change and plant stress management / / edited by Mohammad Wahid Ansari, Anil Kumar Singh and Narendra Tuteja
|
| Pubblicazione: | Chichester, West Sussex, England : , : Wiley, , [2023] |
| ©2023 | |
| Edizione: | First edition. |
| Descrizione fisica: | 1 online resource (462 pages) |
| Disciplina: | 581.35 |
| Soggetto topico: | Plant genetics |
| Plants - Effect of stress on - Genetic aspects | |
| Plants - Metabolism | |
| Vegetation and climate | |
| Soggetto non controllato: | Botany |
| Science | |
| Persona (resp. second.): | AnsariMohammad Wahid |
| SinghAnil Kumar (Principal scientist of plant biotechnology) | |
| TutejaNarendra | |
| Nota di bibliografia: | Includes bibliographical references and index. |
| Nota di contenuto: | Cover -- Title Page -- Copyright Page -- Contents -- List of Contributors -- Foreword -- Preface -- Author Biographies -- Part 1 Views and Visions -- Chapter 1 Boosting Resilience of Global Crop Production Through Sustainable Stress Management -- References -- Chapter 2 Sustaining Food Security Under Changing Stress Environment -- References -- Chapter 3 Crop Improvement Under Climate Change -- 3.1 Crop Diversity to Mitigate Climate Change -- 3.2 Technology to Mitigate Climate Change -- 3.3 Farm Practices to Mitigate Climate Change -- 3.4 Conclusion -- References -- Chapter 4 Reactive Nitrogen in Climate Change, Crop Stress, and Sustainable Agriculture: A Personal Journey -- 4.1 Introduction -- 4.2 Reactive Nitrogen in Climate Change, Agriculture, and Beyond -- 4.3 Nitrogen, Climate, and Planetary Boundaries of Sustainability -- 4.4 Emerging Global Response and India's Leadership in It -- 4.5 Regional and Global Partnerships for Effective Interventions -- 4.6 Building Crop NUE Paradigm Amidst Growing Focus on Stress -- 4.7 From NUE Phenotype to Genotype in Rice -- 4.8 Furthering the Research and Policy Agenda -- References -- Part 2 Climate Change: Global Impact -- Chapter 5 Climate-Resilient Crops for CO2 Rich-Warmer Environment: Opportunities and Challenges -- 5.1 Introduction -- 5.2 Climate Change Trend and Abiotic Stress: Yield Losses Due to Major Climate Change Associated Stresses Heat, Drought and Their Combination -- 5.3 Update on Crop Improvement Strategies Under Changing Climate -- 5.3.1 Advances in Breeding and Genomics -- 5.3.2 Advances in Phenomics and High Throughput Platforms -- 5.3.3 Non-destructive Phenotyping to Exploit Untapped Potential of Natural Genetic Diversity -- 5.4 Exploiting Climate-Smart Cultivation Practices -- 5.5 CO2-Responsive C3 Crops for Future Environment -- 5.6 Conclusion -- References. |
| Chapter 6 Potential Push of Climate Change on Crop Production, Crop Adaptation, and Possible Strategies to Mitigate This -- 6.1 Introduction -- 6.2 Influence of Climate Change on the Yield of Plants -- 6.3 Crop Adaptation in Mitigating Extreme Climatic Stresses -- 6.4 Factors That Limit Crop Development -- 6.5 Influence of Climate Change on Plants' Morphobiochemical and Physiological Processes -- 6.6 Responses of Plant Hormones in Abiotic Stresses -- 6.7 Approaches to Combat Climate Changes -- 6.7.1 Cultural Methodologies -- 6.7.2 Conventional Techniques -- 6.7.3 Strategies Concerned with Genetics and Genomics -- 6.7.4 Strategies of Genome Editing -- 6.7.5 Involvement of CRISPR/Cas9 -- 6.8 Conclusions -- Conflict of Interest Statement -- Acknowledgment -- References -- Chapter 7 Agrifood and Climate Change: Impact, Mitigation, and Adaptation Strategies -- 7.1 Introduction -- 7.2 Causes of Climate Change -- 7.2.1 Greenhouse Gases -- 7.2.2 Fossil Fuel Combustion -- 7.2.3 Deforestation -- 7.2.4 Agricultural Expansion -- 7.3 Impact of Climate Change on Agriculture -- 7.3.1 Crop Productivity -- 7.3.2 Disease Development -- 7.3.3 Plant Responses to Climate Change -- 7.3.4 Livestock -- 7.3.5 Agriculture Economy -- 7.4 Mitigation and Adaptation to Climate Change -- 7.4.1 Climate-Smart Cultural Practices -- 7.4.2 Climate-Smart Agriculture Technologies -- 7.4.3 Stress-Tolerant Varieties -- 7.4.4 Precision Management of Nutrients -- 7.4.5 Forestry and Agroforestry -- 7.5 Conclusions and Future Prospects -- References -- Chapter 8 Dynamic Photosynthetic Apparatus in Plants Combats Climate Change -- 8.1 Introduction -- 8.2 Climate Change and Photosynthetic Apparatus -- 8.3 Engineered Dynamic Photosynthetic Apparatus -- 8.4 Conclusion and Prospects -- References. | |
| Chapter 9 CRISPR/Cas Enables the Remodeling of Crops for Sustainable Climate-Smart Agriculture and Nutritional Security -- 9.1 Introduction: CRISPR/Cas Facilitated Remodeling of Crops -- 9.2 Impact of Climate Changes on Agriculture and Food Supply -- 9.3 Nutritionally Secure Climate-Smart Crops -- 9.4 Novel Game Changing Genome-Editing Approaches -- 9.4.1 Knockout-Based Approach -- 9.4.2 Knock-in-Based Approach -- 9.4.3 Activation or Repression-Based Approach -- 9.5 Genome Editing for Crop Enhancement: Ushering Towards Green Revolution 2.0 -- 9.5.1 Mitigation of Abiotic Stress -- 9.5.2 Alleviation of Biotic Stress -- 9.5.3 Biofortification -- 9.6 Harnessing the Potential of NGS and ML for Crop Design Target -- 9.7 Does CRISPR/Cas Address the Snag of Genome Editing? -- 9.8 Edited Plant Code: Security Risk Assessment -- 9.9 Conclusion: Food Security on the Verge of Climate change -- References -- Part 3 Socioeconomic Aspects of Climate Change -- Chapter 10 Perspective of Evolution of the C4 Plants to Develop Climate Designer C4 Rice as a Strategy for Abiotic Stress Management -- 10.1 Introduction -- 10.2 How Did Plants Evolve to the C4 System? -- 10.2.1 Gene Amplification and Modification -- 10.2.2 Anatomical Preconditioning -- 10.2.3 Increase in Bundle Sheath Organelles -- 10.2.4 Glycine Shuttles and Photorespiratory CO2 Pumps -- 10.2.5 Enhancement of PEPC and PPDK Activity in the Mesophyll Tissue -- 10.2.6 Integration of C3 and C4 Cycles -- 10.3 What Are the Advantages of C4 Plants over C3 Plants? -- 10.4 Molecular Engineering of C4 Enzymes in Rice -- 10.4.1 Green Tissue-Specific Promoters -- 10.4.2 Expressing C4 Enzyme, PEPC in Rice -- 10.4.3 Expressing C4 Enzyme, PPDK in Rice -- 10.4.4 Expressing C4 Enzyme, ME and NADP-ME in Rice -- 10.4.5 Expressing Multiple C4 Enzymes in Rice -- 10.5 Application of CRISPR for Enhanced Photosynthesis. | |
| 10.6 Single-Cell C4 Species -- 10.7 Conclusion -- Acknowledgments -- References -- Chapter 11 Role of Legume Genetic Resources in Climate Resilience -- 11.1 Introduction -- 11.2 Legumes Under Abiotic Stress -- 11.2.1 Legumes Under Drought Stress -- 11.2.2 Legumes Under Waterlogging -- 11.2.3 Legumes Under Salinity Stress -- 11.2.4 Legumes Under Extreme Temperature -- 11.3 Genetic Resources for Legume Improvement -- 11.3.1 Lentil -- 11.3.2 Mungbean -- 11.3.3 Pigeon Pea -- 11.3.4 Chickpea -- 11.4 Conclusion -- References -- Chapter 12 Oxygenic Photosynthesis - a Major Driver of Climate Change and Stress Tolerance -- 12.1 Introduction -- 12.2 Evolution of Chlorophyll -- 12.3 The Great Oxygenation Event -- 12.4 Role of Forest in the Regulation of O2 and CO2 Concentrations in the Atmosphere -- 12.5 Evolution of C4 Plants -- 12.6 The Impact of High Temperature -- 12.7 C4 Plants Are Tolerant to Salt Stress -- 12.8 Converting C3 Plants into C4 - A Himalayan Challenge -- 12.9 Carbonic Anhydrase -- 12.10 Phosphoenolpyruvate Carboxylase -- 12.11 Malate Dehydrogenase -- 12.12 Decarboxylating Enzymes -- 12.12.1 NAD/NADP-Malic Enzyme -- 12.12.2 Phosphoenolpyruvate Carboxykinase -- 12.13 Pyruvate Orthophosphate Dikinase -- 12.14 Regulation of C4 Photosynthetic Gene Expression -- 12.15 Use of C3 Orthologs of C4 Enzymes -- 12.16 Conclusions and Future Directions -- Acknowledgment -- References -- Chapter 13 Expand the Survival Limits of Crop Plants Under Cold Climate Region -- 13.1 Introduction -- 13.2 Physiology of Cold Stress Tolerant Plants -- 13.3 Stress Perception and Signaling -- 13.4 Plant Survival Mechanism -- 13.5 Engineering Cold Stress Tolerance -- 13.6 Future Directions -- Acknowledgment -- References -- Chapter 14 Arbuscular Mycorrhizal Fungi (AMF) and Climate-Smart Agriculture: Prospects and Challenges -- 14.1 Introduction. | |
| 14.2 What Is Climate-Smart Agriculture? -- 14.3 AMF as a Tool to Practice Climate-Smart Agriculture -- 14.3.1 AMF in Increasing Productivity of Agricultural Systems -- 14.3.2 AMF-Induced Resilience in Crops to Climate Change -- 14.3.3 AMF-Mediated Mitigation of Climate Change -- 14.3.4 Agricultural Practices and AMF Symbiosis - Crop Rotations, Tillage, and Agrochemicals -- 14.3.5 AMF Symbiosis and Climate Change -- 14.3.6 Conclusions and Future Perspectives -- Acknowledgment -- References -- Part 4 Plant Stress Under Climate Change: Molecular Insights -- Chapter 15 Plant Stress and Climate Change: Molecular Insight -- 15.1 Introduction -- 15.2 Different Stress Factors and Climate Changes Effects in Plants -- 15.2.1 Water Stress -- 15.2.2 Temperature Stress -- 15.2.3 Salinity Stress -- 15.2.4 Ultraviolet (UV) Radiation Stress -- 15.2.5 Heavy Metal Stress -- 15.2.6 Air Pollution Stress -- 15.2.7 Climate Change -- 15.3 Plant Responses Against Stress -- 15.3.1 Water Stress Responses -- 15.3.2 Temperature Stress Responses -- 15.3.3 Salinity Stress Responses -- 15.3.4 Ultraviolet (UV) Radiation Stress -- 15.3.5 Heavy Metal Stress Responses -- 15.3.6 Air Pollution Stress Responses -- 15.3.7 Climate Change Responses -- 15.4 Conclusion -- References -- Chapter 16 Developing Stress-Tolerant Plants: Role of Small GTP Binding Proteins (RAB and RAN) -- 16.1 Introduction -- 16.2 A Brief Overview of GTP-Binding Proteins -- 16.3 Small GTP-Binding Proteins -- 16.3.1 RAB -- 16.3.2 RAN -- 16.4 Conclusions -- Acknowledgments -- References -- Chapter 17 Biotechnological Strategies to Generate Climate-Smart Crops: Recent Advances and Way Forward -- 17.1 Introduction -- 17.2 Climate Change and Crop Yield -- 17.3 Effect of Climate Change on Crop Morpho-physiology, and Molecular Level -- 17.4 Plant Responses to Stress Conditions -- 17.5 Strategies to Combat Climate Change. | |
| 17.5.1 Cultural and Conventional Methods. | |
| Sommario/riassunto: | Climate change has had unprecedented consequences for plant metabolism and plant growth. In botany, adverse effects of this kind are called plant stress conditions; in recent years, the plant stress conditions generated by climate change have been the subject of considerable study. Plants have exhibited increased photosynthesis, increased water requirements, and more. There is an urgent need to understand and address these changes as we adapt to drastic changes in the global climate. Presenting a comprehensive guide to the effects of global climate change on plants and plant metabolism, this text introduces and describes each climate change-related condition and its components, analysing resulting stress conditions, the environmental factors which ameliorate or exacerbate them, and possible solutions. The result is a thorough introduction to this critical subject for the future of our biome. |
| Titolo autorizzato: | Global climate change and plant stress management |
| ISBN: | 1-119-85855-0 |
| 1-119-85853-4 | |
| Formato: | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione: | Inglese |
| Record Nr.: | 9910830738903321 |
| Lo trovi qui: | Univ. Federico II |
| Opac: | Controlla la disponibilità qui |