Qianyan Liang’s research while affiliated with Yangtze River Fisheries Research Institute and other places

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Publications (2)


Transcriptomic network underlying physiological alterations in the stem of Myricaria laxiflora in response to waterlogging stress
  • Article

September 2024

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9 Reads

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1 Citation

Ecotoxicology and Environmental Safety

Linbao Li

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Yang Su

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Di Wu

Overview of the observable phenotypes and summary of the metabolomic profiles in control and treatments. (A) Pictures of the Adiantum plants grown under different stress and control conditions. (B) Heatmap of the relative intensities of the metabolites accumulated in Adiantum leaves after different treatments. (C) Principal component analysis and (D) Heatmap of the Pearson’s Correlation Coefficient for the detected metabolites in Adiantum leaves after different stress treatments. (E) Summary of the differentially accumulated metabolites in Adiantum leaves under different stress conditions. Where, CK = control, DW05 = half-waterlogging for 5 days, DW10 = half-waterlogging for 10 days, SW05 = drought for 5 days, and SWF05 = day five after rewatering.
Half-waterlogging driven metabolomic changes in Adiantum leaves. (A) Changes in the accumulation pattern of major compound classes after 5 days of half waterlogging. The bars represent the sum of the relative intensities of compounds included in each class. (B) top and bottom 10 accumulated compounds in Adiantum leaves after 5 days of half waterlogging, and (C) scatter plot showing the pathways to which the DAMs were significantly enriched after 5 days of half waterlogging. (D) Changes in the accumulation pattern of major compound classes after 10 days of half waterlogging. The bars represent the sum of the relative intensities of compounds included in each class. (E) top and bottom 10 accumulated compounds in Adiantum leaves after 10 days of half waterlogging, and (F) scatter plot showing the pathways to which the DAMs were significantly enriched after 10 days of half waterlogging.
Drought stress and rewatering driven metabolomic changes in Adiantum leaves. (A) Changes in the accumulation pattern of major compound classes after 5 days of drought stress. The bars represent the sum of the relative intensities of compounds included in each class. (B) top and bottom 10 accumulated compounds in Adiantum leaves after 5 days of drought stress, and (C) scatter plot showing the pathways to which the DAMs were significantly enriched 5 days after drought stress. (D) Changes in the accumulation pattern of major compound classes on day five after rewatering. The bars represent the sum of the relative intensities of compounds included in each class. (E) top and bottom 10 accumulated compounds in Adiantum leaves on day five after rewatering, and (F) scatter plot showing the pathways to which the DAMs were significantly enriched on day five after rewatering.
of differential gene expression in Adiantum leaves after half-waterlogging, drought stress, and rewatering conditions. (A) Bar chart showing the number of differentially expressed genes and (B) Venn diagram of differential genes in Adiantum leaves. Where, CK = control, DW05 = half-waterlogging for 5 days, DW10 = half-waterlogging for 10 days, SW05 = drought stress for 5 days, and SWF05 = day five after rewatering.
Half-waterlogging stress driven transcriptome changes in Adiantum leaves. (A) Heat map representation of expression profiles for differentially regulated genes in response to 5 days of half-waterlogging stress. (B) Heat map representation of expression profiles for differentially regulated genes in response to 10 days of half-waterlogging stress. (C) Scatter plot showing the pathways to which the DEGs were significantly enriched after 5 days of half-waterlogging. (D) Scatter plot showing the pathways to which the DEGs were significantly enriched after 10 days of half-waterlogging. Where, CK = control, DW05 = half-waterlogging for 5 days, and DW10 = half-waterlogging for 10 days.

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Metabolomic and transcriptomic responses of Adiantum (Adiantum nelumboides) leaves under drought, half-waterlogging, and rewater conditions
  • Article
  • Full-text available

April 2023

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113 Reads

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4 Citations

Introduction: Adiantum nelumboides (Adiantum) is an endangered fern with a narrow distribution along the Yangtze River in China. Due to its cliff-dwelling habit, it experiences water stress conditions, which further endangers its survival. However, no information is available about its molecular responses to drought and half-waterlogging conditions. Methods: Here, we applied five and ten days of half-waterlogging stress, five days of drought stress, and rewatering after five days of drought stress, and studied the resulting metabolome profiles and transcriptome signatures of Adiantum leaves. Results and Discussion: The metabolome profiling detected 864 metabolites. The drought and half-waterlogging stress induced up-accumulation of primary and secondary metabolites including amino acids and derivatives, nucleotides and derivatives, flavonoids, alkaloids, and phenolic acid accumulation in Adiantum leaves. Whereas, rewatering the drought-stressed seedlings reversed most of these metabolic changes. Transcriptome sequencing confirmed the differential metabolite profiles, where the genes enriched in pathways associated with these metabolites showed similar expression patterns. Overall, the half-waterlogging stress for 10 days induced large-scale metabolic and transcriptomic changes compared to half-waterlogging stress for 05 days, drought stress for 05 days or rewatering for 05 days. Conclusion: This pioneering attempt provides a detailed understanding of molecular responses of Adiantum leaves to drought and half-waterlogging stresses and rewater conditions. This study also provides useful clues for the genetic improvement of Adiantum for drought/half-waterlogging stress tolerance.

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Citations (2)


... Also, carotenoid participates in salt stress tolerance in Arabidopsis thaliana and Actinidia deliciosa [47]. Upon waterlogging stress, the content of ABA (carotenoids serving as important precursors of ABA) was sharply decreased, alongside the decreased mRNA levels of the genes involved in the corresponding biosynthesis pathway, in the stem of Myricaria laxiflora and the root of Prunus persica [48,49], with this study suggesting that carotenoid biosynthesis is less involved in resistance to waterlogging stress. ...

Reference:

The Expression Profile of Genes Related to Carotenoid Biosynthesis in Pepper Under Abiotic Stress Reveals a Positive Correlation with Plant Tolerance
Transcriptomic network underlying physiological alterations in the stem of Myricaria laxiflora in response to waterlogging stress
  • Citing Article
  • September 2024

Ecotoxicology and Environmental Safety

... Re-watering often (partially) reversed the changes of many metabolites induced by drought stress. However, notable differences were found between species (Liang et al., 2023;Shen et al., 2022;Warren et al., 2012). For instance, in some Eucalyptus species, further increases of some metabolites such as fructose, glucose and proto-quercitol decrease osmotic potential during re-watering, which are considered as helping plants cope with future water stress (Warren et al., 2012). ...

Metabolomic and transcriptomic responses of Adiantum (Adiantum nelumboides) leaves under drought, half-waterlogging, and rewater conditions