Zinc biofortification of wheat through fertilizer and genotype management

Abstract

This study investigated the responses of two wheat varieties, Alvand (Zn-inefficient) and Pishtaz (Zn-efficient), to various zinc (Zn) fertilization methods to determine optimal strategies for enhancing wheat growth and grain quality. The primary aim of this research was to evaluate the effects of various Zn fertilization strategies, including foliar applications of Zn sulfate and Zn-EDTA with and without urea, as well as synthetic Zn amino acid complexes, along with soil applications of Zn sulfate, on the yield and nutritional quality of grains in these two contrasting wheat varieties. The results revealed that wheat varieties responded differently to Zn treatments. While Alvand showed a promising trend of elevated grain yield with foliar zinc sulfate application, Pishtaz exhibited a stronger response to foliar treatments like Zn-Met and Zn-EDTA + urea. Yield components as 1000-grain weight and spike weight, were significantly influenced by Zn fertilization. Foliar application of zinc sulfate + urea enhanced 1000-grain weight in Alvand, whereas Zn-EDTA + urea substantially increased spike weight in Pishtaz. Soil application of zinc sulfate was found to be as an effective method to enhance grain Zn content. Furthermore, the Zn concentrations in flour, straw, bran, and roots elucidated the complex patterns of Zn distribution among various plant tissues. Soil applications were particularly effective in increasing Zn levels in flour and bran, while foliar treatments influenced Zn content in straw and roots. Overall, this research highlights the importance of Zn fertilization strategies for different wheat varieties biofortification. These findings can provide practical implications for sustainable wheat production, addressing Zn deficiency challenges, and advancing food security worldwide. Further exploration into the underlying mechanisms of these responses is encouraged to refine Zn management practices for wheat cultivation.