Flooding Stress: Acclimations and Genetic Diversity

Abstract

Flooding is an environmental stress for many natural and man-made ecosystems worldwide. Genetic diversity in the plant response to flooding includes alterations in architecture, metabolism, and elongation growth associated with a low O₂ escape strategy and an antithetical quiescence scheme that allows endurance of prolonged submergence. Flooding is frequently accompanied with a reduction of cellular O₂ content that is particularly severe when photosynthesis is limited or absent. This necessitates the production of ATP and regeneration of NAD⁺ through anaerobic respiration. The examination of gene regulation and function in model systems provides insight into low-O₂-sensing mechanisms and metabolic adjustments associated with controlled use of carbohydrate and ATP. At the developmental level, plants can escape the low-O₂ stress caused by flooding through multifaceted alterations in cellular and organ structure that promote access to and diffusion of O₂. These processes are driven by phytohormones, including ethylene, gibberellin, and abscisic acid. This exploration of natural variation in strategies that improve O₂ and carbohydrate status during flooding provides valuable resources for the improvement of crop endurance of an environmental adversity that is enhanced by global warming.