Drought drives reversible disengagement of root-mycorrhizal symbiosis

The increasing frequency and severity of droughts pose a major threat to agriculture, food security and ecosystems. Plants respond to water deficit by adjusting growth and metabolism to enhance survival; these adjustments impact the soil microorganisms interacting with plant roots. Plants establish symbiotic relationships with arbuscular mycorrhizal fungi which supply soil nutrients in exchange for carbon metabolites via an intricate dual-species interface within roots. These fungi are dependent upon host-derived photosynthates and are thus potentially vulnerable to plant perturbations during drought. Here, we demonstrate that the plant-mycorrhizal relationship is dynamic when water becomes limiting. During water deficit, rice de-prioritizes nutrient acquisition gene regulatory networks, including its AM symbiotic program, in a strategy conserved with tomato. The fungal symbiont correspondingly represses its growth, undergoing metabolic quiescence, coupled with decommissioning of hyphae within the host’s root. Following re-watering, the host re-engages with its partner fungus, re-invigorating fungal growth and arbuscule establishment. This coordinate, reversible and enduring inter-organismal association may aid host survival under transient stress, but suggests that mutualisms in native and crop plants are potentially fragile in increasingly erratic climates.