1 120

MPB_2024v15n6

1 Introduction 68
2.1 Traditional cultivation methods 69
5.1 Rubber tree (Hevea brasiliensis) 73
5.2 Poplar species 74
6 Potential Benefits and Risks 75
6.1 Economic impact 75
6.2 Environmental benefits 75
6.3 Ethical and ecological concerns 75
7 Future Research Directions 75
7.1 Innovative genetic techniques 75
8 Concluding Remarks 76
1 Introduction 80
2 Genomic Basis of Wheat Diseases 81
3 Genomic Selection and Disease Resistance 82
4 Association Analysis and Disease Resistance Gene 83
5 Application of Gene Editing Technologies in Whea 84
7 Multi-Omics Integration Strategies 86
8 Challenges and Solutions in Genomic Breeding 87
9 Future Perspectives 88
1 Introduction 94
2 Innovation and Utilization of High-Yield Germpla 95
2.1 Exploration of high-yield germplasm resources 95
2.2 Application of genomic selection in high-yield 95
2.3 Molecular improvement of high-yield germplasm 96
3 Innovation and Utilization of Wheat Disease Resi 96
3.1 Innovation of disease resistance traits in whe 96
3.2 Identification and transfer of resistance gene 97
3.3 Multigene resistance strategy for disease-resi 97
4 Innovation and Utilization of Wheat Stress Resis 98
4.1 Exploration and application of drought- and sa 98
4.2 Molecular breeding for stress tolerance traits 98
4.3 Environmental adaptability of stress tolerance 98
5 Technological Advances in Wheat Germplasm Innova 99
5.1 Application of modern molecular breeding techn 99
5.2 Application of transgenic and gene editing tec 100
5.3 Integration of omics technologies 100
6 Success Stories of Germplasm Innovation in Wheat 100
6.1 Development and promotion of high-yield, disea 100
6.2 Commercial application of stress-tolerant whea 100
6.3 Development of comprehensive resistance variet 101
7 Future Research Directions and Trends 101
7.1 Diversified strategies for wheat germplasm inn 101
7.2 Germplasm innovation in the context of climate 101
7.3 Integration of wheat germplasm innovation with 101
8 Concluding Remarks 102

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