| Summary: | Wheat (<i>Triticum aestivum</i> L.) is a vital cereal crop for food security in Pakistan. In Zn-deficient soils, its productivity and quality suffer, affecting grain yield, Zn bioavailability, and nutrition, which can lead to malnutrition. Field experiments were conducted using factorial randomized block design at the Agricultural Research Institute (ARI) Tarnab, Peshawar, Pakistan to evaluate the impact of wheat genotypes (G<sub>1</sub>-TRB-72-311 synthetic hexaploid, G<sub>2</sub>-TRB-89-348 advanced line, and G<sub>3</sub>-Pirsabak-19-approved variety), Zn application methods (AM<sub>1</sub>: no Zn application, AM<sub>2</sub>: seed priming with 0.5% Zn, AM<sub>3</sub>: soil application of 10 kg ha<sup>−1</sup> Zn, and AM<sub>4</sub>: foliar application of 0.5% Zn), and the experiment also explored the use of ZSB (BF<sub>1</sub>: with bacteria, BF<sub>0</sub>: without bacteria) to cope with Zn deficiency. The study revealed significant impacts on wheat’s Zn content, uptake, and nutrient efficiency, arising from genotypes variance, Zn application approaches, and ZSB. TRB-72-311 synthetic hexaploid genotype with 0.5% foliar Zn and ZSB excelled, enhancing grain (17.8%) and straw Zn (23.1%), increasing total Zn uptake (55.0%), reducing grain phytic acid (11.7%), and boosting Zn-related efficiencies in wheat. These results prompt further discussion regarding the potential implications for agricultural practices. In conclusion, utilizing the TRB-72-311 genotype with 0.5% foliar Zn application and ZSB enhances wheat’s Zn content, uptake, grain quality, and addresses malnutrition.
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