Plant Macronutrient Use Efficiency

<p>1. Molecular and Genetic Basis of Plant Macronutrient Use Efficiency: Concepts, Opportunities, and Challenges<br>2. Role of Nutrient-Efficient Plants for Improving Crop Yields: Bridging Plant Ecology, Physiology, and Molecular Biology<br>3. Macronutrient Sensing and Signaling in Plants<br>4. The Significance of Nutrient Interactions for Crop Yield and Nutrient Use Efficiency<br>5. The Contribution of Root Systems to Plant Nutrient Acquisition<br>6. Molecular Genetics to Discover and Improve Nitrogen Use Efficiency in Crop Plants<br>7. The Role of Root Morphology and Architecture in Phosphorus Acquisition: Physiological, Genetic, and Molecular Basis<br>8. Potassium Sensing, Signaling, and Transport: Toward Improved Potassium Use Efficiency in Plants<br>9. Understanding Calcium Transport and Signaling, and its use Efficiency in Vascular Plants<br>10. The Role of Calcium in Plant Signal Transduction Under Macronutrient Deficiency Stress<br>11. Magnesium Homeostasis Mechanisms and Magnesium use Efficiency in Plants<br>12. Advances in Understanding Sulfur Utilization Efficiency in Plants<br>13. Water Availability and Nitrogen use in Plants: Effects, Interaction, and Underlying Molecular Mechanisms<br>14. NPK Deficiency Modulates Oxidative Stress in Plants<br>15. Genetic Improvements of Traits for Enhancing NPK Acquisition and Utilization Efficiency in Plants<br>16. Endophytic Bacteria and Rare Earth Elements; Promising Candidates for Nutrient use Efficiency in Plants<br>17. Introduction to GWAS and MutMap for Identification of Genes/QTL using Next-Generation Sequencing<br>18. Transgenic Approaches for Improving Phosphorus use Efficiency in Plants<br>19. Transgenic Approaches for Improving Nitrogen and Potassium use Efficiency in Plants<br>20. Future Climate Change and Plant Macronutrient use Efficiency</p>