Habitat preference and vulnerability to drought of three Hypericum species of the páramo

Páramos are tropical alpine ecosystems where climate change is expected to cause yet unknown consequences for plant growth, ecosystem structure, ecosystem function and the provision of ecosystem services. To quantify the relationship between environmental factors (abiotic and biotic) and the spatial...

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Bibliographic Details
Published in:Plant ecology & diversity 2022-12, Vol.15 (5-6), p.281-295
Main Authors: Ayarza-Páez, Alejandra, Garzon-Lopez, Carol X., Lasso, Eloisa
Format: Article
Language:English
Subjects:
Alpine environments
Andes
Cavitation
Climate change
Colombia
drone photography
Drought
Ecological function
Ecosystem services
Ecosystem structure
Ecosystems
Environmental factors
Environmental risk
Geographical distribution
Habitat preferences
Hypericum
Moisture content
Moisture effects
Moisture gradient
Physiology
Plant growth
Population decline
Safety margins
Soil moisture
Soil temperature
Soil water
Spatial distribution
Species
Structure-function relationships
tropical alpine ecosystems
Vegetation
Vegetation cover
Vessels
vulnerability curve
Water content
Water deficit
Water potential
Xylem
xylem cavitation
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Summary:Páramos are tropical alpine ecosystems where climate change is expected to cause yet unknown consequences for plant growth, ecosystem structure, ecosystem function and the provision of ecosystem services. To quantify the relationship between environmental factors (abiotic and biotic) and the spatial distribution of three common Hypericum species in the páramo and their physiological vulnerability to drought. We recorded soil water content, soil temperature, and vegetation cover in 10 plots along a moisture gradient. Additionally, we measured a series of physiological traits associated with the risk of drought-induced mortality. We found that H. goyanesii and H. juniperinum mainly grew in areas with high soil water content, and similar high vegetation cover. These two species had wider xylem vessels, showed anisohydric behaviour and were equally vulnerable to cavitation with low safety margins against hydraulic failure. H. mexicanum grew in places with less vegetation cover, lower soil water content, and higher soil temperatures. H. mexicanum showed a different strategy that probably allows it to thrive in these conditions; it maintains high values of water potential at noon and has narrower xylem vessels, making it less vulnerable to cavitation. The distribution of the three Hypericum species in the páramo responds essentially to soil water content, in line with the physiological mechanisms of the species to cope with water deficit. Hypericum species from moist habitats could decline if longer drought episodes become more common in the future.
ISSN:1755-0874
1755-1668
DOI:10.1080/17550874.2022.2143731