Foods (Aug 2024)

Non-Targeted Metabolomics Analysis of <i>γ</i>–Aminobutyric Acid Enrichment in Germinated Maize Induced by Pulsed Light

  • Liangchen Zhang,
  • Xiaojing Liu,
  • Liwei Xu,
  • Mengxi Xie,
  • Miao Yu

DOI
https://doi.org/10.3390/foods13172675
Journal volume & issue
Vol. 13, no. 17
p. 2675

Abstract

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Pulsed light is an emerging technique in plant physiology recognized for its ability to enhance germination and accumulate γ–aminobutyric acid in maize. Pulsed light involves exposing plants to brief, high-intensity bursts of light, which can enhance photosynthesis, improve growth, and increase resistance to environmental stresses. Despite its promising potential, the specific metabolic changes leading to γ–aminobutyric acid enrichment in maize induced by pulsed light are not fully understood. This study addresses this gap by quantifying key nutrients and γ–aminobutyric acid-related compounds during maize germination and investigating the underlying mechanisms using non-targeted metabolomics. Our findings indicate that pulsed light significantly promotes maize germination and accelerates the hydrolysis of proteins, sugars, and lipids. This acceleration is likely due to the activation of enzymes involved in these metabolic pathways. Additionally, pulsed light markedly increases the content of glutamic acid and the activity of glutamate decarboxylase, which are crucial for γ–aminobutyric acid synthesis. Moreover, pulsed light significantly reduces the activity of γ–aminobutyric transaminase, thereby inhibiting γ–aminobutyric acid decomposition and resulting in a substantial increase in γ–aminobutyric acid content, with a 27.20% increase observed in germinated maize following pulsed light treatment. Metabolomic analysis further revealed enrichment of metabolic pathways associated with γ–aminobutyric acid, including amino acid metabolism, carbohydrate metabolism, plant hormone signal transduction, energy metabolism, pyrimidine metabolism, and ABC transporters. In conclusion, pulsed light is a robust and efficient method for producing sprouted maize with a high γ–aminobutyric acid content. This technique provides a novel approach for developing sprouted cereal foods with enhanced nutritional profiles, leveraging the physiological benefits of γ–aminobutyric acid, which include stress alleviation and potential health benefits for humans.

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