Unraveling the role of δ‐zeins in methionine bio‐fortification of maize

Background and Objectives Maize is a major ingredient of animal feed. However, its nutritional quality is poor due to the deficiency of essential amino acid methionine. The animal feed, prepared as a corn–legume mixture to balance the nutritional quality, remains deficient in methionine. Therefore,...

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Bibliographic Details
Published in:Cereal chemistry 2024-05, Vol.101 (3), p.583-593
Main Authors: Devi, Veena, Sethi, Mehak, Singh, Alla, Chaudhary, Dharam P.
Format: Article
Language:English
Subjects:
animal feed
maize bio‐fortification
methionine
qPCR
δ‐zeins
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Summary:Background and Objectives Maize is a major ingredient of animal feed. However, its nutritional quality is poor due to the deficiency of essential amino acid methionine. The animal feed, prepared as a corn–legume mixture to balance the nutritional quality, remains deficient in methionine. Therefore, the bio‐fortification of maize for methionine is the best option to make nutritionally balanced animal and poultry feed. The present study was designed to evaluate the profile of zeins and the expression profile of methionine‐associated target genes in high‐ and low‐methionine maize. Findings Results of sodium dodecyl sulfate‐polyacrylamide gel electrophoresis revealed that the 10‐kDa zein was accumulated during kernel development, and its accumulation was higher in high methionine lines. Gene expression analysis through real‐time polymerase chain reaction revealed that higher expression of 10‐ and 18‐kDa zeins is associated with higher methionine accumulation. Conclusions The above results indicate that 10‐ and 18‐kDa genes are the potential targets for the methionine bio‐fortification in maize, which is required for animal and poultry feed. Significance and Novelty The present study suggests that 10‐ and 18‐kDa genes are the major source of methionine, and the regulation of these genes is crucial to enhancing the methionine content in maize. The results indicate that these genes are potential targets for genetic engineering in maize to enhance methionine accumulation.
ISSN:0009-0352
1943-3638
DOI:10.1002/cche.10762