Effects of multiple climate change factors on the tall fescue-fungal endophyte symbiosis: infection frequency and tissue chemistry

• Climate change (altered CO₂, warming, and precipitation) may affect plant-microbial interactions, such as the Lolium arundinaceum-Neotyphodium coenophialum symbiosis, to alter future ecosystem structure and function. • To assess this possibility, tall fescue tillers were collected from an existing...

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Bibliographic Details
Published in:The New phytologist 2011-02, Vol.189 (3), p.797-805
Main Authors: Brosi, Glade B., McCulley, Rebecca L., Bush, Lowell P., Nelson, Jim A., Classen, Aimée T., Norby, Richard J.
Format: Article
Language:English
Subjects:
09 BIOMASS FUELS
ALKALOIDS
Alkaloids - metabolism
atmospheric precipitation
Carbon dioxide
Carbon Dioxide - pharmacology
CELLULOSE
Cellulose - metabolism
CHEMISTRY
Climate Change
Climate effects
CLIMATES
CLIMATIC CHANGE
Climatic conditions
climatic factors
COMMUNITIES
Ecological effects
Ecosystem structure
ECOSYSTEMS
elevated atmospheric gases
Endophytes
Endosymbionts
Environmental changes
ergovaline
Festuca arundinacea subsp. arundinacea
fungal endophyte
Fungi
Grasses
HEMICELLULOSE
Hot Temperature
infection
Infections
LIGNIN
Lolium
Lolium - physiology
Lolium arundinaceum
Microorganisms
Mycorrhizae - physiology
Neotyphodium
Neotyphodium coenophialum
NITROGEN
Nitrogen - metabolism
nitrogen content
plant–microbe symbiosis
PRECIPITATION
Rain
Stress, Physiological
Structure-function relationships
Symbionts
SYMBIOSIS
Symbiosis - drug effects
tall fescue
temperature
Tillers
Tissue
Tissue analysis
tissue chemistry
Water temperature
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Summary:• Climate change (altered CO₂, warming, and precipitation) may affect plant-microbial interactions, such as the Lolium arundinaceum-Neotyphodium coenophialum symbiosis, to alter future ecosystem structure and function. • To assess this possibility, tall fescue tillers were collected from an existing climate manipulation experiment in a constructed old-field community in Tennessee (USA). Endophyte infection frequency (EIF) was determined, and infected (E+) and uninfected (E−) tillers were analysed for tissue chemistry. • The EIF of tall fescue was higher under elevated CO₂ (91% infected) than with ambient CO₂ (81%) but was not affected by warming or precipitation treatments. Within E+ tillers, elevated CO₂ decreased alkaloid concentrations of both ergovaline and loline, by c. 30%; whereas warming increased loline concentrations 28% but had no effect on ergovaline. Independent of endophyte infection, elevated CO₂ reduced concentrations of nitrogen, cellulose, hemicellulose, and lignin. • These results suggest that elevated CO₂, more than changes in temperature or precipitation, may promote this grass-fungal symbiosis, leading to higher EIF in tall fescue in old-field communities. However, as all three climate factors are likely to change in the future, predicting the symbiotic response and resulting ecological consequences may be difficult and dependent on the specific atmospheric and climatic conditions encountered.
ISSN:0028-646X
1469-8137
DOI:10.1111/j.1469-8137.2010.03532.x