Disease and fire interact to influence transitions between savanna–forest ecosystems over a multi‐decadal experiment

Global change is shifting disturbance regimes that may rapidly change ecosystems, sometimes causing ecosystems to shift between states. Interactions between disturbances such as fire and disease could have especially severe effects, but experimental tests of multi‐decadal changes in disturbance regi...

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Bibliographic Details
Published in:Ecology letters 2021-05, Vol.24 (5), p.1007-1017
Main Authors: Pellegrini, Adam F. A., Hein, Andrew M., Cavender‐Bares, Jeannine, Montgomery, Rebecca A., Staver, A. Carla, Silla, Fernando, Hobbie, Sarah E., Reich, Peter B., Williams, John
Format: Article
Language:English
Subjects:
Alternative states
Disturbance
Ecosystem
Ecosystem resilience
Ecosystems
Environmental changes
fire
Fires
forest
Forest ecosystems
forest model
Forests
fungal pathogen
Grassland
Pest outbreaks
plant disease
savanna
Savannahs
Terrestrial ecosystems
tree rings
Trees
Wilt
Woodlands
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Summary:Global change is shifting disturbance regimes that may rapidly change ecosystems, sometimes causing ecosystems to shift between states. Interactions between disturbances such as fire and disease could have especially severe effects, but experimental tests of multi‐decadal changes in disturbance regimes are rare. Here, we surveyed vegetation for 35 years in a 54‐year fire frequency experiment in a temperate oak savanna–forest ecotone that experienced a recent outbreak of oak wilt. Different fire regimes determined whether plots were savanna or forest by regulating tree abundance (r2 = 0.70), but disease rapidly reversed the effect of fire exclusion, increasing mortality by 765% in unburned forests, but causing relatively minor changes in frequently burned savannas. Model simulations demonstrated that disease caused unburned forests to transition towards a unique woodland that was prone to transition to savanna if fire was reintroduced. Consequently, disease–fire interactions could shift ecosystem resilience and biome boundaries as pathogen distributions change. Using a multi‐decadal fire manipulation experiment in a savanna‐forest ecotone that experienced an outbreak of a plant pathogen, we demonstrate that increasing fire frequencies can dampen the effect of disease, and predict that the presence of disease amplifies the efficiency of fire at maintaining savannas. Disease‐fire interactions present an under‐explored mechanism that could contribute to the distribution of savannas and forests as alternative ecosystem states.
ISSN:1461-023X
1461-0248
DOI:10.1111/ele.13719