{"type": "FeatureCollection", "features": [{"id": "10.1007/s10021-020-00512-9", "type": "Feature", "geometry": null, "properties": {"updated": "2026-05-31T06:55:36Z", "type": "Journal Article", "created": "2020-05-21", "title": "Effects of Litter Quality Diminish and Effects of Vegetation Type Develop During Litter Decomposition of Two Shrub Species in an Alpine Treeline Ecotone", "description": "Because climate change is predicted to have a strong impact on high-altitude ecosystems, a better knowledge of litter decomposition in alpine ecosystems is critical to improve our predictions of the effect of climate change on ecosystem processes and services such as nutrient cycling, carbon sequestration, and below-ground biodiversity. To evaluate the effects of vegetation types [alpine shrubland (AS) and alpine meadow (AM)] and litter quality on litter decomposition and related biochemical processes, the decomposition of leaf litter of two dominant shrub species, Sorbus rufopilosa (SR, high quality) and Rhododendron lapponicum (RL, low quality), was studied using the litterbag method in an alpine treeline ecotone on the eastern Tibetan Plateau. After 1 year of decomposition, cellulolytic enzyme activities and gram-negative bacterial biomass were higher in shrubland than in meadow. However, higher fungal biomass, fungal/bacteria ratio and ligninolytic activity were observed in meadow than in shrubland after 2 years of decomposition. During the first year of decomposition, litter decomposition was faster in shrubland than in meadow probably due to the home-field advantage (HFA) effect and the bacteria-dominated decomposition, whereas in later decomposition stages, litter decomposition was faster in meadow than in shrubland, as the HFA effect diminished and fungal-dominated decomposition of recalcitrant components took over. These results indicated that litter quality effects were generally strongest in the first year and diminished in later stages when the effect of vegetation type in incubation sites developed.", "keywords": ["Lignocellulolytic enzyme", "2. Zero hunger", "0106 biological sciences", "Litter quality", "Litter decomposition", "500", "15. Life on land", "Soil carbon", "01 natural sciences", "Alpine treeline ecotone", "[SDE.BE] Environmental Sciences/Biodiversity and Ecology", "13. 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Ongoing warming-induced encroachment by shrubs and trees risks turning  this sink into a CO2 source, resulting in a positive feedback on climate  warming. To advance mechanistic understanding of how shifts in mycorrhizal  types affect long-term carbon (C) and nitrogen (N) stocks, we studied  small-scale soil depth profiles of fungal communities and C-N dynamics  across a subarctic-alpine forest-heath vegetation gradient. Belowground  organic stocks decreased abruptly at the transition from heath to forest,  linked to the presence of certain tree-associateds ectomycorrhizal fungi  that contribute to decomposition when mining N from organic matter. In  contrast, ericoid mycorrhizal plants and fungi were associated with  organic matter accumulation and slow decomposition. 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To evaluate the effects of vegetation types [alpine shrubland (AS) and alpine meadow (AM)] and litter quality on litter decomposition and related biochemical processes, the decomposition of leaf litter of two dominant shrub species, Sorbus rufopilosa (SR, high quality) and Rhododendron lapponicum (RL, low quality), was studied using the litterbag method in an alpine treeline ecotone on the eastern Tibetan Plateau. After 1 year of decomposition, cellulolytic enzyme activities and gram-negative bacterial biomass were higher in shrubland than in meadow. However, higher fungal biomass, fungal/bacteria ratio and ligninolytic activity were observed in meadow than in shrubland after 2 years of decomposition. 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