Abstract
Cultures of Nasturtium officinale were cultivated in vitro under illumination with different wavelengths of light-emitting diode (LED) light (white LED light—WLED, blue light—B, red light—R, 70% red and 30% blue light—RB, 50% green, 35% red and 15% blue light—RBG, 50% yellow, 35% red and 15% blue light—RBY, 50% far red, 35% red and 15% blue light—RBfR, 50% UV, 35% red and 15% blue light—RBUV, darkness—D), and under white fluorescent light (WF)—control conditions. The study investigated the influence of the applied lighting conditions on biomass growth and the production of glucosinolates, phenolic compounds, as well as photosynthetic pigments, and soluble sugars. The study showed a significant beneficial effect of the RBG light on biomass growth (Gi = 11.81 after 20 days) and the production of glucosinolates. The total glucosinolate content under these conditions increased 5.8 and 1.4 times in comparison with the WF light and D condition, respectively, reaching 237.92 mg 100 g−1 DW. The production of phenolic compounds, sugars, and photosynthetic pigments was comparable to the production under the control conditions. The antioxidant potential of extracts from the cultivated biomass was assessed by the CUPRAC, DPPH, and FRAP assays. Extracts obtained from the biomass of cultures grown under the RBG light had an antioxidant potential similar to that of the control cultures. This is the first report providing evidence of the stimulating effect of light quality on the biomass yield and production of glucosinolates by N. officinale microshoot cultures in vitro.
Highlights
Plant biotechnology strategies may be used to manipulate the production of valuable secondary metabolites responsible for the biological activity of different plant species
The measurements were done in triplicate
This study evaluated for the first time the influence of different lighting conditions on biomass growth, the production of glucosinolates, phenolic compounds, soluble sugars, and photosynthetic pigments, as well as on antioxidant potential in agar microshoot cultures of N. officinale
Summary
Plant biotechnology strategies may be used to manipulate the production of valuable secondary metabolites responsible for the biological activity of different plant species. Studies have shown that light can stimulate the production of different groups of secondary metabolites such as anthocyanins (Zhong et al 1991), polyamines (Shin et al 2004), polyphenols (Szopa et al 2018), phenylpropanoids (Kubica et al 2020), and other biologically active compounds, e.g. artemisinin, digoxin, taxol, or vinblastine (Ramakrishna and Ravishankar 2011). (Robert Brown; described earlier by Linnaeus as Sisymbrium nasturtium-aquaticum), from the family Brassicaceae, known as watercress. It is a rare perennial, aquatic or semiaquatic herb with characteristic creeping or floating stems, native to Europe, North Africa, and Asia (Klimek-Szczykutowicz et al 2018). The Red List of Threatened Species of the International Union for Conservation of Nature has classified this species as a plant of least concern in Europe (IUCN)
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