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Related Experiment Video

Updated: Feb 4, 2026

JenaTron - An Experimental Approach to Study the Effects of Plant History and Soil History on Grassland Ecosystem Functioning
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Multifunctionality changes with plant functional groups in Antarctica.

Hanwen Cui1, Shuyan Chen2, Ziyang Liu1

  • 1State Key Laboratory of Herbage Improvement and Grassland Agro-ecosystems, College of Ecology, Lanzhou University, Lanzhou, Gansu, China.

Ecology
|February 3, 2026
PubMed
Summary
This summary is machine-generated.

Plant presence in Antarctic ecosystems boosts ecosystem multifunctionality, especially with nonvascular and vascular plants. Microbial interactions are key, with direct pathways linking vascular plants to multifunctionality.

Keywords:
Antarcticaecosystem multifunctionalitymicrobial network interactionnonvascular plantplant functional groupsvascular plant

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Area of Science:

  • Ecology
  • Soil Science
  • Microbiology

Background:

  • Ecosystem multifunctionality is crucial but poorly understood in Antarctic terrestrial environments.
  • The specific roles of plant functional groups and their links to ecosystem functions, including carbon cycling and soil health, require further investigation.
  • Understanding plant-soil-microbial interactions is vital for assessing ecosystem multifunctionality in polar regions.

Purpose of the Study:

  • To investigate how plant functional groups (nonvascular and vascular plants) influence ecosystem multifunctionality in Antarctic soils.
  • To determine the direct and indirect pathways (via abiotic and biotic factors) through which plant presence affects multifunctionality.
  • To explore the role of microbial community structure and interactions in mediating the relationship between plants and ecosystem multifunctionality.

Main Methods:

  • Soil samples were collected from five Antarctic sites with varying vegetation cover (bare soil, nonvascular, and vascular plants).
  • Twelve ecosystem functions (e.g., carbon sequestration, nitrogen cycling, SOM decomposition, microbial biomass) were measured to calculate ecosystem multifunctionality.
  • Structural Equation Modeling (SEM) was used to analyze the relationships between plant presence, soil factors, microbial communities, and ecosystem multifunctionality.

Main Results:

  • Ecosystem multifunctionality was significantly higher in areas with nonvascular and vascular plants compared to bare soil.
  • Enhanced carbon sequestration, SOM decomposition, and microbial biomass were observed under plant cover.
  • SEM revealed that increased multifunctionality under nonvascular plants was linked to microbial module hubs, while vascular plants showed a predominant direct pathway to multifunctionality.

Conclusions:

  • Plant functional groups, particularly nonvascular and vascular plants, enhance ecosystem multifunctionality in Antarctic terrestrial ecosystems.
  • Microbial interactions play a significant role, with distinct pathways linking different plant types to multifunctionality.
  • Incorporating microbial dynamics is essential for a comprehensive understanding of ecosystem multifunctionality in polar environments.