# Altitudinal changes induce responses in Coptis chinensis Franch. rhizomes: endophytic communities, metabolite types, and alkaloid contents

**Authors:** Wenli Zhang, Yanan Tang, Ran Luo, Jiang He, Jie Yan, Fei Long, Longyun Li

PMC · DOI: 10.3389/fpls.2026.1777206 · Frontiers in Plant Science · 2026-02-23

## TL;DR

This study explores how altitude affects the medicinal plant Coptis chinensis by influencing its microbial communities and alkaloid content.

## Contribution

The study reveals how altitude influences microbial communities and alkaloid accumulation in Coptis chinensis.

## Key findings

- Alkaloid content in Coptis chinensis increases with altitude, with total alkaloid content rising from 15.97% at 907 m to 17.82% at 1698 m.
- Microbial diversity in the rhizomes varies with altitude, with significant shifts in specific microorganism populations.
- Beneficial endophytes at higher altitudes promote alkaloid biosynthesis through nitrogen utilization and enzyme expression.

## Abstract

Coptis chinensis Franch. is a perennial medicinal plant with huge economic and social benefits, but how altitude affects the accumulation of bioactive compounds through microbial ecosystems remains unexplored. This study examined how microbial communities at different altitudes influence the bioactive components of Coptis chinensis, to help identify beneficial microorganisms for application to its rhizomes. Samples of Coptis chinensis were cultivated at four different altitudes in Shizhu, Chongqing. To characterize the phytochemical profile of Coptis chinensis, nine specific alkaloids were quantified by High Performance Liquid Chromatography (HPLC) and Ultraviolet-Visible Spectrophotometry (UV-Vis), with Liquid Chromatography-Mass Spectrometry (LC-MS) subsequently employed to characterize differential metabolite accumulation at each altitude. Microbial community structure in the rhizomes was analyzed by metagenomic sequencing. Results indicated that the contents of groenlandicine, coptisine, berberine, and total alkaloids increased with altitude, with the total alkaloid content rising from 15.97% at 907 m to 17.82% at 1698 m (P < 0.01). Analysis revealed 912 differential metabolites, with distinct accumulation patterns at different altitudes. Microbial diversity in the rhizomes also varied by altitude, with significant shifts in Mucoromycota, Pseudomonadota, Rhizophagus, and Mesorhizobium populations. Moreover, the relative abundance of these microorganisms was intricately linked to alkaloid content. High altitude significantly enhances alkaloid accumulation in C. chinensis, and this effect is primarily mediated by the enrichment of beneficial endophytes, which promote the biosynthesis of target alkaloids via optimizing nitrogen utilization and inducing the expression of key enzymes.

## Linked entities

- **Chemicals:** groenlandicine (PubChem CID 3084708), coptisine (PubChem CID 72322), berberine (PubChem CID 2353)
- **Species:** Mucoromycota (taxon 1913637), Pseudomonadota (taxon 1224), Rhizophagus (taxon 295919), Mesorhizobium (taxon 68287)

## Full-text entities

- **Diseases:** vomiting (MESH:D014839), diarrhea (MESH:D003967), inflammatory (MESH:D007249), abscesses (MESH:D000038), heart fire (MESH:D006331), infection (MESH:D007239)
- **Chemicals:** glutamate (MESH:D018698), hydrochloric acid (MESH:D006851), Alkaloids (MESH:D000470), Epiberberine (MESH:C061432), polyketide (MESH:D061065), ethanol (MESH:D000431), glycyrrhizin (MESH:D019695), Glycine (MESH:D005998), blood glucose (MESH:D001786), salvianolic acid B (MESH:C076944), water (MESH:D014867), tyrosine (MESH:D014443), tanshinone IIA (MESH:C021751), (S)-reticuline (MESH:C003298), liquiritin (MESH:C512196), nucleotides (MESH:D009711), sulfur compounds (MESH:D013457), jatrorrhizine (MESH:C055785), (S)-tetrahydrocolumbamine (MESH:C092892), N2 (MESH:D009584), triethylamine (MESH:C016162), Alanine (MESH:D000409), carbon (MESH:D002244), palmatine (MESH:C005413), Methanol (MESH:D000432), Phosphorus (MESH:D010758), nitrate (MESH:D009566), O2 (MESH:D010100), coptisine (MESH:C034384), Organoheterocyclic compounds (MESH:D006571), flavonoid (MESH:D005419), Berberine (MESH:D001599), threonine (MESH:D013912), CBGA (MESH:C100679), lipid (MESH:D008055), ammonium hydroxide (MESH:D064753), Nucleosides (MESH:D009705), Lignans (MESH:D017705), columbamine (MESH:C055786), aspartate (MESH:D001224), amino acid (MESH:D000596), serine (MESH:D012694), phenols (MESH:D010636), ammonium bicarbonate (MESH:C027043), arginine (MESH:D001120), Compounds (-), CBDV (MESH:C580853), Potassium (MESH:D011188), magnoflorine (MESH:C001670)
- **Species:** Cannabis sativa (species) [taxon 3483], Paraburkholderia (genus) [taxon 1822464], Fungi (kingdom) [taxon 4751], Trichoderma harzianum (species) [taxon 5544], Flavobacterium (genus) [taxon 237], Coptis chinensis (species) [taxon 261450], Rhizophagus irregularis (species) [taxon 588596], Asarum (genus) [taxon 16728], Salvia miltiorrhiza (Chinese salvia, species) [taxon 226208], Streptomyces (genus) [taxon 1883], Bradyrhizobium (genus) [taxon 374], Artemisia argyi (species) [taxon 259893], Rhizophagus intraradices (species) [taxon 4876], Pseudomonas (RNA similarity group I, genus) [taxon 286], Niastella (genus) [taxon 354354], Bacteria Latreille et al. 1825 (Bacteria stick insect, genus) [taxon 629395], Acidobacteriota (phylum) [taxon 57723], Rhizophagus (genus) [taxon 1129544], Variovorax (genus) [taxon 34072], Rhizobium (genus) [taxon 379], Mesorhizobium (genus) [taxon 68287], Glycyrrhiza uralensis (Chinese licorice, species) [taxon 74613], Ginkgo biloba (ginkgo, species) [taxon 3311]

## Full text

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## Figures

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## References

58 references — full list in the complete paper: https://tomesphere.com/paper/PMC12968305/full.md

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Source: https://tomesphere.com/paper/PMC12968305