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Soil and crop management strategies to prevent iron deficiency in crops

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Abstract

Plants and humans cannot easily acquire iron from their nutrient sources although it is abundant in nature. Thus, iron deficiency is one of the major limiting factors affecting crop yields, food quality and human nutrition. Therefore, approaches need to be developed to increase Fe uptake by roots, transfer to edible plant portions and absorption by humans from plant food sources. Integrated strategies for soil and crop management are attractive not only for improving growing conditions for crops but also for exploiting a plant’s potential for Fe mobilization and utilization. Recent research progress in soil and crop management has provided the means to resolve complex plant Fe nutritional problems through manipulating the rhizosphere (e.g., rhizosphere fertilization and water regulation), and crop management (includes managing cropping systems and screening for Fe efficient species and varieties). Some simple and effective soil management practices, termed ‘rhizosphere fertilization’ (such as root feeding and bag fertilization) have been developed and widely used by local farmers in China to improve the Fe nutrition of fruit plants. Production practices for rice cultivation are shifting from paddy-rice to aerobic rice to make more efficient use of irrigation water. This shift has brought about increases in Fe deficiency in rice, a new challenge depressing iron availability in rice and reducing Fe supplies to humans. Current crop management strategies addressing Fe deficiency include Fe foliar application, trunk injection, plant breeding for enriched Fe crop species and varieties, and selection of cropping systems. Managing cropping systems, such as intercropping strategies may have numerous advantages in terms of increasing Fe availability to plants. Studies of intercropping systems on peanut/maize, wheat/chickpea and guava/sorghum or -maize increased Fe content of crops and their seed, which suggests that a reasonable intercropping system of iron-efficient species could prevent or mitigate Fe deficiency in Fe-inefficient plants. This review provides a comprehensive comparison of the strategies that have been developed to address Fe deficiency and discusses the most recent advance in soil and crop management to improve the Fe nutrition of crops. These proofs of concept studies will serve as the basis for future Fe research and for integrated and optimized management strategies to alleviate Fe deficiency in farmers’ fields.

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Acknowledgements

We thank the National High-tech R&D Program (863 Program, Grant No. 2008AA10Z117), The innovative group grant of NSFC (Grant No. 30821003) and National Natural Science Foundation of China (Grant No. 31071840) for financial support and Dr. Prof. Ross M. Welch (USDA-ARS Robert W. Holly Center for Agriculture and Health, Cornell university campus), Dr. Jiping Liu (USDA-ARS Robert W. Holly Center for Agriculture and Health, Cornell university campus) and Dr. Rui Proenca for critically reading of the manuscript.

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Correspondence to Fusuo Zhang.

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Zuo, Y., Zhang, F. Soil and crop management strategies to prevent iron deficiency in crops. Plant Soil 339, 83–95 (2011). https://doi.org/10.1007/s11104-010-0566-0

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