Abstract
Here we assess the impact of geographically dependent (latitude, longitude, and altitude) changes in bioclimatic (temperature, precipitation, and primary productivity) variability on fungal fruiting phenology across Europe. Two main nutritional guilds of fungi, saprotrophic and ectomycorrhizal, were further separated into spring and autumn fruiters. We used a path analysis to investigate how biogeographic patterns in fungal fruiting phenology coincided with seasonal changes in climate and primary production. Across central to northern Europe, mean fruiting varied by approximately 25 d, primarily with latitude. Altitude affected fruiting by up to 30 d, with spring delays and autumnal accelerations. Fruiting was as much explained by the effects of bioclimatic variability as by their large-scale spatial patterns. Temperature drove fruiting of autumnal ectomycorrhizal and saprotrophic groups as well as spring saprotrophic groups, while primary production and precipitation were major drivers for spring-fruiting ectomycorrhizal fungi. Species-specific phenology predictors were not stable, instead deviating from the overall mean. There is significant likelihood that further climatic change, especially in temperature, will impact fungal phenology patterns at large spatial scales. The ecological implications are diverse, potentially affecting food webs (asynchrony), nutrient cycling and the timing of nutrient availability in ecosystems.
| Original language | English |
|---|---|
| Pages (from-to) | 1306-1315 |
| Number of pages | 10 |
| Journal | Ecology |
| Volume | 99 |
| Issue number | 6 |
| DOIs | |
| Publication status | Published - 1 Jun 2018 |
Funding
We thank Jeffrey Diez and two anonymous reviewers for constructive manuscript comments. Two funding sources are acknowledged for financial support: The Research Council of Norway, project “Climate change impacts on the fungal ecosystem component (ClimFun)” (14 months), and the Swiss National Science Foundation, project “Linking European Fungal Ecology with Climate Variability – Euro-FC” (7.5 months). Dag Endresen is thanked for help with altitude data extraction and coordinate systems conversion. We thank Anders Nielsen for help with NDVI data. We thank all employees and volunteers associated over the years with the collection and management of the fungal and open-source data. The following organizations are acknowledged for originally providing digitized fungal records data to the meta-database: the Austrian Mycological Society and Wolfgang Damon; the Swiss national database (www.swissfungi.ch) and Peter Jakob; Deutsche Gesellschaft fu€r Mykologie (German Mycological Society) and Martin Schmidt; The Danish Fungal Atlas project and Tobias Frøslev, Thomas Læssøe, Jens. H. Petersen and Jan Vesterholt; the Netherlands Mycological Society (NMV) and A. van den Berg; the Mycological Herbarium at the Natural History Museum (University of Oslo); the Slovenian Forestry Institute, the Central database of fungi in Slovenia, the Slovenian Mycological Association, and Nikica Ogris; www.fieldmycology.net for support sources of the UK national database.
UN SDGs
This output contributes to the following UN Sustainable Development Goals (SDGs)
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SDG 13 Climate Action
Austrian Fields of Science 2012
- 106024 Mycology
Keywords
- climate
- distribution
- Europe
- fruit bodies
- fungi
- NDVI
- nutritional mode
- path analysis
- phenology
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