Optimizing <i>Valerianella locusta</i> L. Growth and Metabolism by Combining Red and Blue LED Light: Insights into Plant Physiology, Biochemistry, and Nutraceutical Value

Optimizing <i>Valerianella locusta</i> L. Growth and Metabolism by Combining Red and Blue LED Light: Insights into Plant Physiology, Biochemistry, and Nutraceutical Value

Environmental and health concerns have increased the demand for ready-to-eat vegetables rich in bioactive compounds. This study explores the impact of red and blue (R:B) LED light on the metabolic responses of lamb’s lettuce (<i>Valerianella locusta</i> L.), focusing on sugars, organic a...

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Main Authors: Sonia Monterisi, Carmen Rebollo Vicioso, Monica Yorlady Alzate Zuluaga, Sofia Melchior, Biancamaria Senizza, Gokhan Zengin, Roberto Fattorini, Umberto Lanza, Talita de Oliveira Caretta, Lara Manzocco, Luigi Lucini, Stefano Cesco, Youry Pii
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Plants
Subjects:
lamb’s lettuce (<i>Valerianella locusta</i> L.)
organic acids
phenolic compounds
antioxidant activity
metabolomics
shelf-life
Online Access:https://www.mdpi.com/2223-7747/14/12/1887
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Summary:Environmental and health concerns have increased the demand for ready-to-eat vegetables rich in bioactive compounds. This study explores the impact of red and blue (R:B) LED light on the metabolic responses of lamb’s lettuce (<i>Valerianella locusta</i> L.), focusing on sugars, organic acids, total phenolics, antioxidant activity, and enzyme inhibition. Post-harvest analyses were also conducted to assess shelf-life and microbiological characteristics of the product. The R:B LED treatment significantly enhanced plant growth, with a 133% and 68% increase in shoot fresh and dry weights, respectively, and a 21% increase in leaf area compared to controls (white LED light). Biochemical profiling revealed substantial increases in fructose (255%), sucrose (169%), citric acid (350%), and malic acid (868%) under R:B LED light. Additionally, phenolic content increased by 30%, alongside a notable modulation of 258 secondary metabolites, including flavonoid glycosides, alkaloids, and terpenoids. These biochemical changes contributed to a marked improvement in antioxidant capacity (12–45% across multiple assays) and a 300% increase in α-glucosidase inhibition, suggesting potential antidiabetic properties. Furthermore, post-harvest analysis revealed comparable shelf-life and microbiological safety between R:B and white LED-grown samples. The research highlights the potential of LED light to enhance plant biochemical responses and improve crop quality without affecting post-harvest quality, paving the way for sustainable agricultural innovations.
ISSN:2223-7747

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