Abstract Decreased iron and zinc bioaccessibility, caused by the anti-nutrient phytic acid, is one of the leading reasons for micronutrient deficiency-related disorders. Biofortification of wheat with phytase gene to enhance… Click to show full abstract
Abstract Decreased iron and zinc bioaccessibility, caused by the anti-nutrient phytic acid, is one of the leading reasons for micronutrient deficiency-related disorders. Biofortification of wheat with phytase gene to enhance iron and zinc bioaccessibility appears to be a fitting solution for this problem, especially in developing countries where most of the population belongs to the lower economic sector. However, societal views on crops, particularly crops that are genetically modified (GM) to express a new trait, needs to be changed. Risk assessment of GM crops can play a crucial role in fostering positive public perception, since it is imperative to ensure safety before allowing human consumption. The present study performed compositional and morphological risk assessment of T3 and T4 generations of phytase transgenic wheat by comparing their biochemical and morphological traits. Transgenic plants were analysed for their carbohydrate, protein, starch and phytic acid content along with iron bioaccessibility, zinc bioaccessibility and phytase enzyme activity. Morphological traits studied included plant height, seed number, seed weight and spike number. No significant differences were observed for carbohydrate, protein, starch content and for morphological traits; however, a significant increase was observed in phytase activity as well as iron and zinc bioaccessibility, which correlated with a significant decrease in phytic acid. These results demonstrate that phytase transgenic wheat is as native as local wheat varieties and can potentially increase iron and zinc bioaccessibility.
               
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