Spatial Ecology of the Fungal Genus Xylaria in a Tropical Cloud Forest

Fungal symbioses with plants are ubiquitous, ancient, and vital to both ecosystem function and plant health. However, benefits to fungal symbionts are not well explored, especially in non‐mycorrhizal fungi. The Foraging Ascomycete hypothesis proposes that some wood‐decomposing fungi may shift life‐h...

Full description

Saved in:
Bibliographic Details
Published in:Biotropica 2016-05, Vol.48 (3), p.381-393
Main Authors: Thomas, Daniel C., Vandegrift, Roo, Ludden, Ashley, Carroll, George C., Roy, Bitty A.
Format: Article
Language:English
Subjects:
análisis espacial
Ascomycetes
bosque tropical nublado
Canopies
Cloud forests
decomposer
descomponedor
Ecological function
endophyte
Endophytes
endófitos
Environmental conditions
estrategia de historia de vida
Foraging Ascomycete hypothesis
Forest floor
Habitat preferences
Hipótesis del Ascomiceto Forrajero
host preference
Life history
life-history strategy
preferencia de hospedero
spatial analysis
Tropical Biology
tropical cloud forest
Xylariaceae
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Fungal symbioses with plants are ubiquitous, ancient, and vital to both ecosystem function and plant health. However, benefits to fungal symbionts are not well explored, especially in non‐mycorrhizal fungi. The Foraging Ascomycete hypothesis proposes that some wood‐decomposing fungi may shift life‐history strategies to endophytism to bridge gaps in time and space between suitable substrates. To test this hypothesis we examine spatial relationships of Xylaria endophytic fungi in the forest canopy with Xylaria decomposer fungi on the forest floor. We sampled for fungi of the genus Xylaria using a spatially explicit sampling scheme in a remote Ecuadorian cloud forest, and concurrently carried out an extensive culture‐based sampling of fungal foliar endophytes. We found 36 species of Xylaria in our 0.5 ha plot, 31 of which were found to only occur as fruiting bodies. All five species of Xylaria found as endophytes were also found as fruiting bodies. We also tested the relationships of both stages of these fungi to environmental variables. Decomposer fungi were differentiated by species‐specific habitat preferences, with three species being found closer to water than expected by chance. In contrast, endophytes displayed no sensitivity to environmental conditions, such as host, moisture, or canopy cover. We found evidence of spatial linkage between life stages in two species. We also demonstrate that direct transmission of endophytes from leaves to woody substrates is possible. These results indicate that endophytism may represent one way for decomposer fungi to escape moisture limitation, and that endophytic fungi may act as sources of dispersal for decomposer fungi consistent with predictions of the Foraging Ascomycete hypothesis.
ISSN:0006-3606
1744-7429
DOI:10.1111/btp.12273