# Metabolomics analysis of mechanism of improving quality of Schisandrae chinensis fructus by NO combining with high-temperature stress

**Authors:** Zhaoping Meng, Wei Zhang, Zixian Guo, Liyang Wang, Wenfei Liu, Ling Cao, Yuhua Zhang, Xiangcai Meng

PMC · DOI: 10.1371/journal.pone.0327497 · 2025-07-18

## TL;DR

This study shows that combining nitric oxide with high-temperature stress improves the quality of Schisandra chinensis fruit by boosting antioxidant secondary metabolites.

## Contribution

The study reveals how exogenous NO and high-temperature stress enhance secondary metabolism in Schisandra chinensis fruits.

## Key findings

- Exogenous NO and high-temperature stress increased ROS levels and PAL activity, simulating adversity stress.
- Twenty-two differential metabolites were identified, with 17 secondary metabolites showing increased levels.
- Primary metabolites were redirected to secondary metabolism to defend against ROS under stress conditions.

## Abstract

The fruits of Schisandra chinensis (Turcz.) Baill. (Schisandrae chinensis fructus) are a well-known herbal medicine, known for its hepatoprotective, antidepressant, antioxidant, and sedative-hypnotic properties. Over-exploitation of wild resources led to the rise of cultivation, along with a decrease in quality. Exposure of plants to adversity must generate substantial quantities of reactive oxygen species (ROS) and result in cellular damage. In response, secondary metabolites are produced to neutralize ROS; these secondary metabolites are usually the active ingredient of herbal medicine, so the quality of herbal medicine is closely related to the environment and ROS. The interplay of exogenous Nitric Oxide (NO, supplied as sodium nitroprusside) and high-temperature stress can simulate adversity and improve the quality of Schisandrae chinensis fructus; neverless, the underlying mechanism remains largely unexplored. In this study, we examined the changes in intracellular ROS levels as well as phenylalanine deaminase activities after stress and analyzed the metabolic changes using ultra performance liquid chromatography-quadrupole time-of-flight tandem mass spectrometry (UPLC-Q-TOF-MSE). The results showed that the level of superoxide anion (O2.−) and H2O2 increased by 25.8% and 331%, respectively, the activity of phenylalanine aminotransferase (PAL) by 69.3% on the 2nd day, indicating that combination of exogenous NO with high-temperature stress could lead to physiological states of adversity stress. Twenty-two differential metabolites (VIP ≥ 1) were identified using untargeted metabolomics. 3 primary metabolites, namely mannose, pyruvate, and shikimic acid, together with 2 secondary metabolites, phenylalanine and mevalonic acid, were observed to decrease. 17 secondary metabolites, including Schisandrin A, Schisandrin B, Schisandrin C, Gomisin D, Gomisin G, Gomisin H, Benzoylgomisin H, Benzoylgomisin O,Angeloylgomisin P, Catechin, Isorhamnetin, Luteolin, Cinnamic acid, Hydroxycinnamic acid, Hexahydrocurcumin, Coniferyl alcohol, Phenylalanine, Terpinolene and Mevalonic acid, exhibited increases in their levels by 10.64, 1.84, 1.40, 1.64, 4.46, 8.18, 1.72, 10.20, 2.08, 1.27, 1.57, 1.18, 2.01, 1.12, 1.88, 1.15, and 3.17-fold, respectively. Under stress conditions, intracellular ROS levels increased, and a significant portion of primary metabolites were used for the biosynthesis of secondary metabolites with higher antioxidant activity. This redistribution of metabolic flows from basal metabolism to secondary metabolism to defend against ROS. The combination of exogenous NO with high-temperature enhances secondary metabolism of Schisandra chinensis fruit, which opens new avenues for production of high-quality Schisandra chinensis fructus.

## Linked entities

- **Chemicals:** Nitric Oxide (PubChem CID 145068), sodium nitroprusside (PubChem CID 6604165), superoxide anion (PubChem CID 5359597), H2O2 (PubChem CID 784), mannose (PubChem CID 18950), pyruvate (PubChem CID 107735), shikimic acid (PubChem CID 8742), phenylalanine (PubChem CID 994), mevalonic acid (PubChem CID 449), Schisandrin A (PubChem CID 155256), Schisandrin B (PubChem CID 108130), Schisandrin C (PubChem CID 443027), Gomisin D (PubChem CID 5317799), Gomisin G (PubChem CID 14992067), Gomisin H (PubChem CID 5317803), Benzoylgomisin H (PubChem CID 14992069), Benzoylgomisin O (PubChem CID 91826818), Angeloylgomisin P (PubChem CID 13844273), Catechin (PubChem CID 1203), Isorhamnetin (PubChem CID 5281654), Luteolin (PubChem CID 5280445), Cinnamic acid (PubChem CID 444539), Hydroxycinnamic acid (PubChem CID 637542), Hexahydrocurcumin (PubChem CID 5318039), Coniferyl alcohol (PubChem CID 1549095), Terpinolene (PubChem CID 11463)
- **Species:** Schisandra chinensis (taxon 50507)

## Full-text entities

- **Chemicals:** mannose (MESH:D008358), sodium nitroprusside (MESH:D009599), Phenylalanine (MESH:D010649), O2.- (MESH:D013481), Angeloylgomisin P (-), Luteolin (MESH:D047311), Hexahydrocurcumin (MESH:C569902), Schisandrin C (MESH:C031409), H2O2 (MESH:D006861), Schisandrin A (MESH:C034734), Gomisin D (MESH:C082092), Coniferyl alcohol (MESH:C010559), Cinnamic acid (MESH:C029010), Schisandrin B (MESH:C015499), Terpinolene (MESH:C027009), Catechin (MESH:D002392), ROS (MESH:D017382), Gomisin G (MESH:C034557), NO (MESH:D009569), Mevalonic acid (MESH:D008798), shikimic acid (MESH:D012765), Isorhamnetin (MESH:C047368), pyruvate (MESH:D019289), Hydroxycinnamic acid (MESH:D003373)
- **Species:** Schisandra chinensis (Chinese magnolia-vine, species) [taxon 50507]

## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12273920/full.md

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Source: https://tomesphere.com/paper/PMC12273920