Improving Stress Resilience in Plants

Physiology<br>1. Physiological adaptation of plants to abiotic stresses<br>2. Modulation of physiology in plants through osmolytes application<br>3. Studying the physiology of genetically modified crop plants<br>4. Root traits and water relations in plants under stresses<br>5. Role of soil microbes in modulating the physiological attributes of plants under extreme environmental conditions<br>6. Morphological modulations in plants exposed to abiotic and biotic stresses<br>7. Physiological modulations/ adaptations of plants for improved mineral nutrition under stresses<br>8. Regulation of photosynthesis under stress<br>9. Water relation, photosynthesis and plant growth<br>10. Modification of physiological attributes by nano-fertilizes attributes for improved stress tolerance<br>11. Physiological modification in plants under fungicide and pesticide stress<br><br>Biochemistry<br>12. Modulation of plant biochemistry through excess use of fungicides and herbicides in plants<br>13. Enzyme functioning and environmental stresses<br>14. Plant nitrogen metabolism: effects of stresses and the mitigating role of mineral elements and phytohormones<br>15. Plant nitrogen metabolism: effects of stresses and the mitigating role of compatible osmolytes<br>16. Modulation of sulphur metabolism in plants under stress conditions: role of mineral elements<br>17. Sulphur metabolism and phytohormones interactions in plants under stress<br>18. Antioxidant system: role and regulation under environmental stresses vis-à-vis mineral nutrition<br>19. Understanding the role of plant growth regulators as key players in stress signalling<br>20. Role of phytohormones in improving stress tolerance: Focus on the antioxidant system<br>21. Understanding the role of thiols in stress biology of crop plants<br>22. Ascorbate-Glutathione Pathway: abiotic stress tolerance in plants and modulations by exogenous osmo-protectants<br>23. Photosynthesis: role of antioxidant system and glyoxylase system<br>24. Reactive oxygen species production: production. Signalling, and antioxidant and glyoxylase defence systems<br>25. Understanding the biochemical basis of stress signalling in plants<br>26. Breeding and Plant Stress Tolerance<br>27. Integrated approaches of "omics" for the improvement of stress tolerance in plants<br>28. Understanding the regulatory mechanisms of abiotic stress tolerance in plants by using genomic approaches<br>29. Prognosis for genetic improvement of yield potential of major grain crops under environmental stress<br>30. Genotypic variation for stress tolerance in legume crops<br>31. Genomics-assisted breeding for the development of stress tolerant crop varieties<br>32. Marker assisted selection in plant breeding for stress tolerance<br>33. Recent advances in plant breeding for the improvement of plant stress tolerance: Prospects and limitations<br>34. QTLs for stress tolerance in plants<br>35. CRISPR gene editing and stress tolerance<br>36. Genetic approaches for tolerance to multiple stresses