Abstract
Drought stress poses a significant threat to global agriculture, necessitating innovative strategies to enhance plant resilience. This review highlights the rhizosheath-the soil layer tightly bound to roots by mucilage and microbial biofilms-as a critical but underexplored microbial niche for sustainable drought mitigation. Unlike the vulnerable rhizosphere, the rhizosheath has a cohesive structure that acts as a protective "mini-oasis," preserving moisture and sustaining microbial activity when water is scarce. We synthesize evidence showing that resident rhizosheath bacteria, including genera such as Bacillus, Pseudomonas, and Azospirillum, enhance plant drought tolerance through multiple mechanisms: improving soil structure and water retention, modulating phytohormone levels, facilitating nutrient acquisition, and activating antioxidant and genetic defense pathways in the plant. Despite promising laboratory findings, there has been little field-scale validation of these effects. Here, we critically assess translational challenges and outline future research priorities, such as understanding plant-microbe specificity and optimizing synthetic microbial consortia. Addressing these questions will enable manipulation of the rhizosheath microbiome for development of climate-resilient crops and securing food production in water-limited environments.