# Influence of Cushion Plant Androsace tapete on Nitrogen Uptake Strategies of Associated Alpine Plants

**Authors:** Shuo Xing, Yong-Tao He, Pei-Li Shi, Xing-Liang Xu

PMC · DOI: 10.3390/plants14203232 · Plants · 2025-10-21

## TL;DR

This study shows how the cushion plant Androsace tapete helps other alpine plants by altering their nitrogen uptake strategies in nutrient-poor environments.

## Contribution

The study reveals how A. tapete influences soil nitrogen availability and shifts the nitrogen uptake patterns of associated alpine plants.

## Key findings

- Soil total C, total N, and available NH4+ increased significantly under A. tapete.
- A. tapete prefers NH4+ uptake, while associated plants in control areas use a more balanced nitrogen source.
- Associated plants with A. tapete reduced glycine uptake and increased inorganic N absorption.

## Abstract

In alpine ecosystems, plant growth is often constrained by multiple environmental factors, especially the infertile soils with lower temperature that decelerate the rate of nutrient turnover, thus leading to a diminished availability of nutrients in the soil, notably nitrogen (N), and its different forms, which is a pivotal factor for limiting plant growth and species coexistence in these alpine areas. Androsace tapete (A. tapete) is an endemic species and the most widely distributed cushion plant on the Qinghai–Tibet Plateau (QTP). Its positive interactions can facilitate other associated plants to deal with severe environmental conditions in the alpine grassland ecosystem. The change in soil nutrient availability is one of the main positive interactions, but little is known about how A. tapete changes soil nutrient availability and affects the N uptake pattern of associated plants. This study investigated the N utilization patterns of three associated plant species —Carex atrofusca (C. atrofusca), Cyananthus incanus (C. incanus), and Potentilla saundersiana (P. saundersiana)— growing inside the cushion area A. tapete (CA) and the ambient grassland without cushion plants (CK), using a 15N labeling method to clarify the effect of A. tapete on the N uptake strategies with NH4+, NO3−, and organic N of its associated species. The results showed the following: (1) compared to CK, the soil total C, total N, and available NH4+ contents under the A. tapete showed a significant 47.82%, 40.96%, and 47.33% increase, respectively; (2) A. tapete showed a stronger preference for NH4+ (>80%), whereas the associated species in CK exhibited a more balanced uptake, deriving 39.29–55.59% of N from NO3−, 25.72–44.00% from NH4+, and 16.15–18.69% from glycine. (3) The three associated plants possessing A. tapete significantly reduced their uptake of glycine by 9.76%, 12.55%, and 7.15%, respectively, while the absorption of NH4+ by C. atrofusca and C. incanus increased by 18.46% and 36.11%; meanwhile, NO3− uptake decreased by 8.70% in C. atrofusca and 23.55% in C. incanus. These findings indicated that the A. tapete can change the N uptake pattern of the associated plants growing inside the cushion body, such as enhancing the absorption of inorganic N and decreasing the organic N. This adaptive strategy of the associated plants with cushion plant enables them to counteract the N-limited conditions prevalent in alpine environments, and, as a consequence, facilitates their growth and promotes local plant community diversity in the alpine environment.

## Linked entities

- **Chemicals:** NH4+ (PubChem CID 222), NO3− (PubChem CID 943), glycine (PubChem CID 750)
- **Species:** Androsace tapete (taxon 265249), Carex atrofusca (taxon 241197), Cyananthus incanus (taxon 1045293), Potentilla saundersiana (taxon 667282)

## Full-text entities

- **Chemicals:** C (MESH:D002244), NO3- (MESH:C038619), 15N (-), N (MESH:D009584), glycine (MESH:D005998)
- **Species:** Potentilla saundersiana (species) [taxon 667282], Cyananthus incanus (species) [taxon 1045293], Androsace tapete (species) [taxon 265249], Carex atrofusca (species) [taxon 241197]

## Full text

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## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12566856/full.md

## References

57 references — full list in the complete paper: https://tomesphere.com/paper/PMC12566856/full.md

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Source: https://tomesphere.com/paper/PMC12566856