Abstract
Iron toxicity is a major constraint to rice production, particularly in highly weathered soils of inland valleys in sub-Saharan Africa where the rice growing area is rapidly expanding. There is a wide variation in tolerance of iron toxicity in the rice germplasm. However, the introgression of tolerance traits into high-yielding germplasm has been slow owing to the complexity of the tolerance mechanisms and large genotype-by-environment effects. We review current understanding of tolerance mechanisms, particularly those involving below-ground plant-soil interactions. Until now these have been less studied than above-ground mechanisms. We cover processes in the rhizosphere linked to exclusion of toxic ferrous iron by oxidation, and resulting effects on the mobility of nutrient ions. We also cover the molecular physiology of below-ground processes controlling iron retention in roots and root-shoot transport, and also plant iron sensing. We conclude that future breeding programmes should be based on well-characterized molecular markers for iron toxicity tolerance traits. To successfully identify such markers, the complex tolerance response should be broken down into its components based on understanding of tolerance mechanisms, and tailored screening methods should be developed for individual mechanisms.
Highlights
Iron toxicity refers to a set of severely yield-limiting disorders associated with high concentrations of reduced ferrous iron (Fe[II]) in submerged lowland rice soils (Becker & Asch, 2005; Sahrawat, 2005)
Estimates of the rice growing area in sub-Saharan Africa affected by iron toxicity vary from 20% to 60%, and estimated yield losses vary from 10% to 90% (Rodenburg et al, 2014; Sikirou et al, 2015)
There is a need for an integrated approach to understand the mechanisms and genetics of iron toxicity tolerance, taking into account the complex below-ground plant–soil interactions. We focus on these below-ground processes, and interactions between genotype adaptations and mineral nutrient deficiencies
Summary
Iron toxicity refers to a set of severely yield-limiting disorders associated with high concentrations of reduced ferrous iron (Fe[II]) in submerged lowland rice soils (Becker & Asch, 2005; Sahrawat, 2005). Zhang, Xu, Yi, & Gong, 2012) and rice ferritin genes OsFER1 and OsFER2 (Aung, Masuda, et al, 2018; Finatto et al, 2015; Quinet et al, 2012) are strongly up-regulated in roots and shoots by excess iron (Figure 2). This effect may be greater under nutrient deficiencies as a result of leaky root membranes, resulting in exacerbated iron toxicity.
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