Faculty Mentor
Dr. Stephanie Kivlin
Department (e.g. History, Chemistry, Finance, etc.)
Ecology and Evolutionary Biology
College (e.g. College of Engineering, College of Arts & Sciences, Haslam College of Business, etc.)
College of Arts & Sciences
Year
2019
Abstract
Fungi are key to belowground ecosystem function, yet post-fire recovery of fungal communities has not been examined in many ecosystems. A massive wildfire in 2016 in the Great Smoky Mountains National Park (GSMNP) and surrounding urban landscape (Gatlinburg, TN) presented a novel opportunity to study post-fire fungal response within an urban-forest ecosystem. We surveyed soils and plants in GSMNP and Gatlinburg, TN 1.5-2 years post-fire to assess colonization of arbuscular mycorrhizal fungi (AMF, aseptate hyphae) and decomposers/pathogens (septate hyphae) from 13 plant species across 18 sites, (9 park, 9 urban).
Overall, colonization by aseptate (intraradical R2= 0.46, P= 0.03) and septate (intraradical R2= 0.19, P= 0.01; extraradical R2= 0.07, P= 0.03) hyphae decreased with increasing fire intensity. This pattern was primarily driven by GSMNP sites (intraradical, R2= 0.28, P< 0.01; extraradical R2= 0.26, P< 0.01), with colonization decreasing in roots but not soils—suggesting soil recovery precedes root recovery for symbiotic AMF. Meanwhile, the decrease in intra- and extraradical septate colonization suggests this community recovers more slowly after wildfire than AMF. The sensitivity of our fungal communities to wildfire alongside predicted changes in wildfire regimes suggests declines in fungal abundance throughout southeastern Appalachia.
Included in
Fungal response to wildfire in a southeastern wildland-urban interface
Fungi are key to belowground ecosystem function, yet post-fire recovery of fungal communities has not been examined in many ecosystems. A massive wildfire in 2016 in the Great Smoky Mountains National Park (GSMNP) and surrounding urban landscape (Gatlinburg, TN) presented a novel opportunity to study post-fire fungal response within an urban-forest ecosystem. We surveyed soils and plants in GSMNP and Gatlinburg, TN 1.5-2 years post-fire to assess colonization of arbuscular mycorrhizal fungi (AMF, aseptate hyphae) and decomposers/pathogens (septate hyphae) from 13 plant species across 18 sites, (9 park, 9 urban).
Overall, colonization by aseptate (intraradical R2= 0.46, P= 0.03) and septate (intraradical R2= 0.19, P= 0.01; extraradical R2= 0.07, P= 0.03) hyphae decreased with increasing fire intensity. This pattern was primarily driven by GSMNP sites (intraradical, R2= 0.28, P< 0.01; extraradical R2= 0.26, P< 0.01), with colonization decreasing in roots but not soils—suggesting soil recovery precedes root recovery for symbiotic AMF. Meanwhile, the decrease in intra- and extraradical septate colonization suggests this community recovers more slowly after wildfire than AMF. The sensitivity of our fungal communities to wildfire alongside predicted changes in wildfire regimes suggests declines in fungal abundance throughout southeastern Appalachia.