Biogeography of plant-associated fungal symbionts in mountain ecosystems: A meta-analysis

Aim: Predicting the potential for climate change to disrupt host-microbe symbioses requires basic knowledge of the biogeography of these consortia. In plants, fungal symbionts can ameliorate the abiotic Stressors that accompany climate warming and thus could influence plants under a changing climate...

Full description

Saved in:
Bibliographic Details
Published in:Diversity & distributions 2017-09, Vol.23 (9/10), p.1067-1077
Main Authors: Kivlin, Stephanie N., Lynn, Joshua S., Kazenel, Melanie R., Rudgers, Jennifer A.
Format: Article
Language:English
Subjects:
Abundance
Altitude
altitudinal gradients
arbuscular mycorrhizal fungi
Arbuscular mycorrhizas
Biodiversity
BIODIVERSITY RESEARCH
Biogeography
Climate
Climate change
Climate prediction
Consortia
Documents
Ecosystems
ectomycorrhizal fungi
Ectomycorrhizas
Elevation
Endophytes
ericoid mycorrhizal fungi
foliar endophytes
Forecasting
Functional groups
fungal distributions
Fungi
Global warming
Grasses
Identification methods
Meta-analysis
Mountain ecosystems
Plant diversity
Plants (botany)
Predictions
root endophytes
Shrubs
Species diversity
Symbionts
Symbiosis
Citations: Items that this one cites
Items that cite this one
Online Access:Request full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Aim: Predicting the potential for climate change to disrupt host-microbe symbioses requires basic knowledge of the biogeography of these consortia. In plants, fungal symbionts can ameliorate the abiotic Stressors that accompany climate warming and thus could influence plants under a changing climate. Forecasting future plant-microbe interactions first requires knowledge of current fungal symbiont distributions, which are poorly resolved relative to the distributions of plants. Location: We used meta-analysis to summarize the biogeographic distributions of plant-fungal symbionts in mountain ecosystems worldwide, because these ecosystems are likely to be among the first to experience climate change-induced range shifts. Methods: We analysed 374 records from 53 publications to identify general trends, pinpoint areas in need of greater study and develop reporting guidelines to facilitate future syntheses. Results: Elevational patterns varied strongly among fungal and plant functional groups. Fungal diversity and abundance increased with altitude for the ectomycorrhizal fungi. However, arbuscular mycorrhizal fungi and localized foliar endophytes declined in either abundance or diversity with altitude. In shrubs, fungal abundance increased with elevation, but in C₃ grasses, fungal abundance declined with elevation. Altitudinal patterns in fungal composition were stronger than gradients in fungal abundance or diversity, suggesting that species turnover contributes more to elevational gradients in fungal symbionts than does variation in abundance or richness. Plant functional groups were overrepresented by C₃ grasses and trees, with surprisingly few data on sedges or shrubs, despite their ecological dominance in mountain ecosystems. Similarly, epich-loae, ericoid mycorrhizal fungi and root endophytes were understudied relative to other fungal groups. Main Conclusions: Meta-analysis revealed broad biogeographic patterns in plant-fungal symbiont abundance, diversity and composition that inform predictions of future distributions.
ISSN:1366-9516
1472-4642
DOI:10.1111/ddi.12595