Integrated multi-omic analysis reveals the carbon metabolism-mediated regulation of polysaccharide biosynthesis by suitable light intensity in Bletilla striata leaves

Bletilla striata, valued for its medicinal and ornamental properties, remains largely unexplored in terms of how light intensity affects its physiology, biochemistry, and polysaccharide formation. In this 5-month study, B. striata plants were exposed to three different light intensities: low light (...

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Veröffentlicht in:Plant physiology and biochemistry 2024-09, Vol.214, p.108872, Article 108872
Hauptverfasser: Zhu, Jiao, Cai, Youming, Li, Xin, Yang, Liuyan, Zhang, Yongchun
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Sprache:eng
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Zusammenfassung:Bletilla striata, valued for its medicinal and ornamental properties, remains largely unexplored in terms of how light intensity affects its physiology, biochemistry, and polysaccharide formation. In this 5-month study, B. striata plants were exposed to three different light intensities: low light (LL) (5–20 μmol m−2·s−1), middle light (ML) (200 μmol m−2·s−1), and high light (HL) (400 μmol m−2·s−1). The comprehensive assessment included growth, photosynthetic apparatus, chlorophyll fluorescence electron transport, and analysis of differential metabolites based on the transcriptome and metabolome data. The results indicated that ML resulted in the highest plant height and total polysaccharide content, enhanced photosynthetic apparatus performance and light energy utilization, and stimulated carbon metabolism and carbohydrate accumulation. HL reduced Chl content and photosynthetic apparatus functionality, disrupted OEC activity and electron transfer, stimulated carbon metabolism and starch and glucose accumulation, and hindered energy metabolism related to carbohydrate degradation and oxidation. In contrast, LL facilitated leaf growth and increased chlorophyll content but decreased plant height and total polysaccharide content, compromised the photosynthetic apparatus, hampered light energy utilization, stimulated energy metabolism related to carbohydrate degradation and oxidation, and inhibited carbon metabolism and carbohydrate synthesis. Numerous genes in carbon metabolism were strongly related to polysaccharide metabolites. The katE and cysK genes in carbon metabolism were strongly related not only to polysaccharide metabolites, but also to genes involved in polysaccharide biosynthesis. Our results highlight that light intensity plays a crucial role in affecting polysaccharide biosynthesis in B. striata, with carbon metabolism acting as a mediator under suitable light intensity conditions. •Transcriptome and metabolome enrich in carbon metabolism in different light intensity.•Low light inhibits carbon metabolism and results more energy wastage.•Middle light enhanced photosynthetic performance and stimulated carbon metabolism.•Middle light intensity exhibits highest total polysaccharide contents.•Carbon metabolism mediated polysaccharide biosynthesis in suitable light intensity.
ISSN:0981-9428
1873-2690
1873-2690
DOI:10.1016/j.plaphy.2024.108872