Combination of red and blue light induces anthocyanin and other secondary metabolite biosynthesis pathways in an age-dependent manner in Batavia lettuce

Combination of red and blue light induces anthocyanin and other secondary metabolite biosynthesis pathways in an age-dependent manner in Batavia lettuce

•Batavia lettuce grown in red-blue light had more anthocyanin than fluorescent light.•Anthocyanin accumulation was higher in mature stage than early stage lettuce.•Both red-blue light and plant age jointly affected the transcriptome profile.•Mature plant in red-blue light induced more secondary meta...

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Veröffentlicht in:Plant science (Limerick) 2021-09, Vol.310, p.110977-110977, Article 110977
Hauptverfasser: Sng, Benny Jian Rong, Mun, Bonggyu, Mohanty, Bijayalaxmi, Kim, Mijung, Phua, Zhi Wei, Yang, Hyunsoo, Lee, Dong-Yup, Jang, In-Cheol
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Anthocyanin
Anthocyanins - metabolism
Gene Expression Regulation, Plant - radiation effects
Lactuca - metabolism
Lactuca - radiation effects
Lettuce
Light
Photosynthesis - radiation effects
Plant age
Plant Leaves - metabolism
Plant Leaves - radiation effects
Red-blue light
Secondary metabolite
Transcriptome - genetics
Transcriptome analysis
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container_start_page 110977
container_title Plant science (Limerick)
container_volume 310
creator Sng, Benny Jian Rong
Mun, Bonggyu
Mohanty, Bijayalaxmi
Kim, Mijung
Phua, Zhi Wei
Yang, Hyunsoo
Lee, Dong-Yup
Jang, In-Cheol
description •Batavia lettuce grown in red-blue light had more anthocyanin than fluorescent light.•Anthocyanin accumulation was higher in mature stage than early stage lettuce.•Both red-blue light and plant age jointly affected the transcriptome profile.•Mature plant in red-blue light induced more secondary metabolite biosynthesis genes.•Red-blue light caused metabolic flux that enriched anthocyanin biosynthesis pathway. Lettuce is commonly consumed around the world, spurring the cultivation of green- and red-leaf varieties in indoor farms. One common consideration for indoor cultivation is the light wavelengths/spectrum, which is an important factor for regulating growth, development, and the accumulation of metabolites. Here, we show that Batavia lettuce (Lactuca sativa cv. “Batavia”) grown under a combination of red (R) and blue (B) light (RB, R:B = 3:1) displayed better growth and accumulated more anthocyanin than lettuce grown under fluorescent light (FL). Anthocyanin concentration was also higher in mature stage than early stage lettuce. By performing a comparative transcriptome analysis of early and mature stage lettuce grown under RB or FL (RB or FL-lettuce), we found that RB induced the expression of genes related to oxidation-reduction reaction and secondary metabolite biosynthesis. Furthermore, plant age affected the transcriptome response to RB, as mature RB-lettuce had six times more differentially expressed genes than early RB-lettuce. Also, genes related to the accumulation of secondary metabolites such as flavonoids and anthocyanins were more induced in mature RB-lettuce. A detailed analysis of the anthocyanin biosynthesis pathway revealed key genes that were up-regulated in mature RB-lettuce. Concurrently, branching pathways for flavonol and lignin precursors were down-regulated.
doi_str_mv 10.1016/j.plantsci.2021.110977
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Lettuce is commonly consumed around the world, spurring the cultivation of green- and red-leaf varieties in indoor farms. One common consideration for indoor cultivation is the light wavelengths/spectrum, which is an important factor for regulating growth, development, and the accumulation of metabolites. Here, we show that Batavia lettuce (Lactuca sativa cv. “Batavia”) grown under a combination of red (R) and blue (B) light (RB, R:B = 3:1) displayed better growth and accumulated more anthocyanin than lettuce grown under fluorescent light (FL). Anthocyanin concentration was also higher in mature stage than early stage lettuce. By performing a comparative transcriptome analysis of early and mature stage lettuce grown under RB or FL (RB or FL-lettuce), we found that RB induced the expression of genes related to oxidation-reduction reaction and secondary metabolite biosynthesis. Furthermore, plant age affected the transcriptome response to RB, as mature RB-lettuce had six times more differentially expressed genes than early RB-lettuce. Also, genes related to the accumulation of secondary metabolites such as flavonoids and anthocyanins were more induced in mature RB-lettuce. A detailed analysis of the anthocyanin biosynthesis pathway revealed key genes that were up-regulated in mature RB-lettuce. 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Lettuce is commonly consumed around the world, spurring the cultivation of green- and red-leaf varieties in indoor farms. One common consideration for indoor cultivation is the light wavelengths/spectrum, which is an important factor for regulating growth, development, and the accumulation of metabolites. Here, we show that Batavia lettuce (Lactuca sativa cv. “Batavia”) grown under a combination of red (R) and blue (B) light (RB, R:B = 3:1) displayed better growth and accumulated more anthocyanin than lettuce grown under fluorescent light (FL). Anthocyanin concentration was also higher in mature stage than early stage lettuce. By performing a comparative transcriptome analysis of early and mature stage lettuce grown under RB or FL (RB or FL-lettuce), we found that RB induced the expression of genes related to oxidation-reduction reaction and secondary metabolite biosynthesis. Furthermore, plant age affected the transcriptome response to RB, as mature RB-lettuce had six times more differentially expressed genes than early RB-lettuce. Also, genes related to the accumulation of secondary metabolites such as flavonoids and anthocyanins were more induced in mature RB-lettuce. A detailed analysis of the anthocyanin biosynthesis pathway revealed key genes that were up-regulated in mature RB-lettuce. 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Lettuce is commonly consumed around the world, spurring the cultivation of green- and red-leaf varieties in indoor farms. One common consideration for indoor cultivation is the light wavelengths/spectrum, which is an important factor for regulating growth, development, and the accumulation of metabolites. Here, we show that Batavia lettuce (Lactuca sativa cv. “Batavia”) grown under a combination of red (R) and blue (B) light (RB, R:B = 3:1) displayed better growth and accumulated more anthocyanin than lettuce grown under fluorescent light (FL). Anthocyanin concentration was also higher in mature stage than early stage lettuce. By performing a comparative transcriptome analysis of early and mature stage lettuce grown under RB or FL (RB or FL-lettuce), we found that RB induced the expression of genes related to oxidation-reduction reaction and secondary metabolite biosynthesis. 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subjects Anthocyanin
Anthocyanins - metabolism
Gene Expression Regulation, Plant - radiation effects
Lactuca - metabolism
Lactuca - radiation effects
Lettuce
Light
Photosynthesis - radiation effects
Plant age
Plant Leaves - metabolism
Plant Leaves - radiation effects
Red-blue light
Secondary metabolite
Transcriptome - genetics
Transcriptome analysis
title Combination of red and blue light induces anthocyanin and other secondary metabolite biosynthesis pathways in an age-dependent manner in Batavia lettuce
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