Microbial assisted zinc biofortification of wheat germplasm for the amelioration of zinc malnutrition

Microbial assisted zinc biofortification of wheat germplasm for the amelioration of zinc malnutrition

Abstract Zinc (Zn) is an important micronutrient with vital biological roles and its deficiency causes serious complications both in plants and human cells. The present research aims to introduce a sustainable intervention to improve zinc bioavailability, partitioning and biofortification in wheat g...

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Main Authors: Sundus Malik, Aqib Iqbal, Iqbal Munir, Khaled S. Allemailem, Faris Alrumaihi, Wanian M. Alwanian, Ayman M. Mousa, Wafa Abdullah I. Al-Megrin, Amir Muhammad Khan, Salimullah Khan
Format: Article
Language:English
Published: Nature Portfolio 2025-07-01
Series:Scientific Reports
Subjects:
Wheat
Zinc-solubilizing bacteria
Zinc oxide
TaZIPs
TabZIPs
Biofortification
Online Access:https://doi.org/10.1038/s41598-025-09946-4
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Summary:Abstract Zinc (Zn) is an important micronutrient with vital biological roles and its deficiency causes serious complications both in plants and human cells. The present research aims to introduce a sustainable intervention to improve zinc bioavailability, partitioning and biofortification in wheat genotypes through the use of zinc solubilizing bacteria. Three bacterial strains; Pseudomonas lurida (DJ4), Pseudomonas aeruginosa (DJ5) and Pseudomonas fluorescens (DJ13), previously isolated from a forest soil in Dir, Pakistan with zinc solubilization potential were used during this study. The maximum of 242.34 and 108.08 µg·l−1 gluconic and glucuronic acid, respectively, was produce by the bacterial strain DJ13 in the presence of zinc oxide and consequently, a decrease in medium pH from 7.0 to 4.63 was noted. Further, root colonization potential of these bacterial strains with wheat genotypes (Atta Habib, Sirin and Pak China) was confirmed by scanning electron microscope (SEM). Similarly, the zinc uptake and translocation potential of the eight wheat genotypes under no zinc, ZnSO4.7H2O supplementation or inoculation with DJ13 was evaluated in a pot experiment in greenhouse. Wheat genotypes Zincol 2016, Sirin and Atta Habib attained higher grain zinc content after DJ13 inoculation (57.87, 63.55 and 60.47 mg·kg−1 respectively). Genetic differences in zinc uptake, translocation and grain accumulation in wheat genotypes under different growth conditions were noted to be because of differential expression of ZIP transporters. High expression levels of TaZIP1, TaZIP4, TaZIP13, and TabZIP1 were correlated with increased root uptake, TaZIP1 and TabZIP1 were correlated with zinc translocation and TaZIP5 with grain accumulation. In conclusion, this research demonstrated the capacity to solubilize zinc and establish a synergistic interaction with wheat by specific bacterial strains, particularly Pseudomonas fluorescens (DJ13), significantly enhancing zinc uptake, translocation, and mobilization. These strains also modulated the expression of ZIP genes, leading to increased zinc partitioning in wheat grains. Consequently, these rhizobacteria present a highly effective biofertilizer strategy for zinc biofortification of grains and the optimization of wheat growth and development.
ISSN:2045-2322

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