Soil protist diversity in the Swiss western Alps is better predicted by topo-climatic than by edaphic variables

Détails

ID Serval
serval:BIB_E3E74898CE9E
Type
Article: article d'un périodique ou d'un magazine.
Collection
Publications
Titre
Soil protist diversity in the Swiss western Alps is better predicted by topo-climatic than by edaphic variables
Périodique
Journal of Biogeography
Auteur(s)
Seppey C.W.V., Broennimann O., Buri A., Yashiro E., Pinto-Figueroa E., Singer D., Blandenier Q., Mitchell E.A.D., Niculita-Hirzel H., Guisan A., Lara E.
ISSN
1365-2699
Statut éditorial
In Press
Peer-reviewed
Oui
Langue
anglais
Résumé
Aim: Trends in spatial patterns of macroscopic organisms diversity can be well predicted from correlative models, using topo-climatic variables for plants and animals allowing inference over large scales. By contrast, soil microorganisms diversity is generally considered as mostly driven by edaphic variables and, therefore, difficult to extrapolate on a large spatial scale based on predictive models. Here, we compared the power of topo-climatic vs. edaphic variables for predicting the diversity of various soil protist groups at the regional scale.
Location: Swiss western Alps.
Taxa: Full protist community and nine clades belonging respectively to three functional groups: parasites (Apicomplexa, Peronosporomycetes, Phytomyxea), phagotrophs (Sarcomonadea, Tubulinea, Spirotrichea) phototrophs (Chlorophyta, Trebouxiophyceae, Diatomeae).
Methods: We extracted soil DNA from 178 sites along a wide range of elevations with a random-stratified sampling design. We defined protist Operational Taxonomic Units assemblages by metabarcoding of the V4 region of the rRNA small sub-unit gene. We assessed and modelled the diversity (Shannon index) patterns of all above-mentioned taxonomic groups based on topo-climatic (topography, slope southness, slope steepness and average summer temperature) and edaphic (soil temperature, relative humidity, pH, electroconductivity, phosphorus percentage, carbon/nitrogen, loss on ignition and shale percentage) variables in Generalized Additive Models (GAM).
Results: The respective significance of topo-climatic and edaphic variables varied among taxonomic and – to a certain extent – functional groups: while many variables explained significantly the diversity of the three phototrophs this was less the case for the three parasites. Topo-climatic variables had a better predictive power than edaphic variables, yet predictive power varied among taxonomic groups.
Main conclusions: Topo-climatic variables (particularly slope steepness and summer temperature if we consider their significance in the GAMs) were, on average, better predictors of protist diversity at the landscape scale than edaphic variables. However, the predictive power of these variables on diversity differed considerably among taxonomic groups; such relationships may be due to direct and/or indirect (e.g. biotic) influences (like with parasitic taxa, where low predictive power is most likely explained by the absence of information on the hosts distribution). Future prospects include using such spatial models to predict hotspots of diversity and disease outbreaks.

Mots-clé
Algae, functional groups, macroecology, microbial ecology, parasites, predictive modelling, protozoa, meadow soils, spatial modelling
Création de la notice
04/10/2019 16:48
Dernière modification de la notice
17/10/2019 8:30
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