PLANT CELL BIOTECHNOLOGY AND MOLECULAR BIOLOGY

Millets, often referred to as "nutri-cereals," are gaining global recognition for their remarkable resilience to abiotic stresses such as drought, salinity, and extreme temperatures. These small-seeded cereals possess unique physiological and biochemical adaptations that enable them to survive in marginal environments. Among these mechanisms, root exudates play a crucial role in stress adaptation by modulating soil microbiota, enhancing nutrient acquisition, and mitigating oxidative damage. This review explores the composition, function, and significance of root exudates in millet stress tolerance, highlighting key exudates such as organic acids, flavonoids, osmolytes, and phytohormones. It also discusses genetic and environmental factors influencing root exudation, along with emerging analytical techniques for studying exudate profiles. Furthermore, the potential applications of root exudate research in breeding climate-resilient millet varieties are examined, with a focus on microbiome engineering and targeted metabolomic approaches. A deeper understanding of root exudates can revolutionize millet breeding by enhancing stress resilience and improving nutrient uptake efficiency. In order to harness the potential of root exudates for stress mitigation, various strategies can be employed, including genetic improvement, microbial inoculation, and agronomic interventions. The study concluded that root exudates play a crucial role in millet adaptation to abiotic stress, influencing nutrient acquisition, microbial interactions, and overall plant resilience. The dynamic interactions between root exudates and soil microbiota further enhance stress adaptation by recruiting beneficial microbes that improve nutrient uptake and mitigate stress-induced damage. Future research directions include integrating exudate traits into millet improvement programs and leveraging advanced technologies such as metabolomics and synthetic biology for enhanced stress tolerance. By unlocking the potential of root exudates, millet cultivation can be optimized for food security and sustainable agriculture in the face of climate change.