When a wildfire obliterates a forest, the first life to rise from the ashes is usually a fungus one of several species that cannot complete its life cycle in the absence of fire. Scientists have long argued about where and how such pyrophilous (fire-loving) fungi survive, sometimes for decades, between fires. A new study finds that some of these fungi hideout in the tissues of mosses and lichens. The findings appear in the journal Fungal Ecology.

The University of Illinois at Urbana-Champaign, By Diana Yates

© Daniel Raudabaugh | Fire-loving fungi are among the first organisms to appear on the forest floor after a fire, followed closely by mosses and lichens.

"We have this specific group of fungi that we see after a fire; they never occur before a fire," said study co-author Andrew Miller, a mycologist with the Illinois Natural History Survey at the University of Illinois. "You're only going to see the fruiting bodies what most people recognize as a mushroom after a fire."
Scientists have come up with several hypotheses to explain where pyrophilous fungi live when they're not reproductively active, Miller said. Some think the spores drift into a newly burned zone from elsewhere, but how those spores could develop in the absence of fire isn't clear, he said. Some suggest the  is present in the soil, either as a spore or a storage organ that somehow lasts for decades between fires and isn't consumed by fire.
"Our hypothesis was that some fungi are present in the pre-fire system in the bodies of mosses and lichens," Miller said. "Then they become reproductive when the moss or lichen burns up."
To test this hypothesis, Miller and his colleagues collected mosses, lichens and  from burned and unburned areas in and around the Great Smoky Mountains National Park after a 2016 wildfire. Illinois postdoctoral scientist Daniel Raudabaugh led the research with Miller and the University of Tennessee ecology and evolutionary biology professors Brandon Matheny and Karen W. Hughes.
To determine if the fungi were inside the mosses and lichens rather than riding along on their surfaces, the researchers disinfected the moss and lichen samples before testing their innards to see if any fungi were inside.
The team found DNA from pyrophilous fungi inside the surface-sterilized mosses and lichens from burned and unburned areas. They also found DNA from pyrophilous fungi in the soils inside and outside the burn area. That latter discovery is interesting, Miller said, since pyrophilous fungi do not fruit outside a burn zone. The presence of their DNA there might suggest they're persisting in the soil as fire-resistant spores.
Another possibility is that some of the fungal spores from the burned areas drifted into the unburned zones, leaving a DNA "signature" in the soil, Hughes said. The DNA might persist there longer than the spores could survive in the soil, she said.
"I see the moss or  as a protective capsule that gets burned away in a fire and the fungus is not severely harmed," Raudabaugh said. "It will burn that outer coating off, and the fungus falls onto the  and then starts growing."
The researchers say there is more to learn about how the fungi persist in the environment.
"There are some things that we still don't understand, such as how pyrophilous fungi live for decades inside mosses and lichens between  events," Matheny said. "However, evidence suggests that these  have taken up residence inside these other organisms on the forest floor,  or tree canopy, which has contributed to their lack of detection by traditional means."

This article was originally published by the University of Illinois at Urbana-Champaign.
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