Suchergebnisse

Intro -- Contents -- Chapter 1: The Utilization of Speed Breeding and Genome Editing to Achieve Zero Hunger -- Introduction -- Evolution of SB and Genome Editing -- Time-Saving Tools for Achieving Zero Hunger -- Plant Breeding Acceleration Through SB -- Genome Editing Strategies: A Progressive Way Toward Zero Hunger Goal -- Enhancing Resistance via Genome Editing -- Increasing Abiotic Tolerance via Genome Editing -- Improving Herbicide Tolerance Through Genome Editing -- Improvement of Crop Yield Through Genome Editing -- Optimization of Nutrient Use Efficiency Through Genome Editing -- Integration of SB and Genome Editing Technologies for Achievement of Zero Hunger -- Shortcomings of SB and Genome Editing -- Conclusion -- References -- Chapter 2: Multiomics Approach for Crop Improvement Under Climate Change -- Introduction -- Climate Change Scenario and Its Impact on Crop Yield -- Application of Advanced Omics Approaches -- Transcriptomics -- Proteomics -- Metabolomics -- Ionomics -- Phenomics -- Emerging Molecular Techniques -- Zinc Finger Nuclease (ZFN) -- Oligonucleotide-Directed Mutagenesis (ODM) -- RNA-Dependent DNA Methylation (RdDM) -- Reverse Breeding -- Agro-Infiltration -- Synthetic Genomics -- Widely Studied Crop -- Conclusion and Future Prospects -- References -- Chapter 3: The Intervention of Multi-Omics Approaches for Developing Abiotic Stress Resistance in Cotton Crop Under Climate Change -- Introduction -- Impact of Abiotic Stresses on Cotton -- Physiological Responses of Cotton Toward Abiotic Stresses -- Molecular Changes Due to Abiotic Stresses -- Regulation of miRNAs During Abiotic Stresses -- Hormonal Regulation During Abiotic Stress -- Calcium Signaling During Abiotic Stress -- Type of Abiotic Stress-Induced Genes -- Role of Heat Shock Proteins During Abiotic Stress -- Role of Transcription Factors Under Abiotic Stress.