Why bioluminescent fungi glow in the dark

By: Liz Kimbrough
June 13, 2013



Aristotle (384–322 BC) reported a mysterious light, distinct from fire, emanating from decaying wood. Pliny the Elder (23–79 AD) mentioned feasting on a glowing, sweet fungus found on trees in France and, in the late fifteenth century, a Dutch consul gave accounts of Indonesian peoples using fungal fruits to illuminate forest pathways. Bioluminescent fungi have intrigued generations of observers, and a handful of scientists still carry that torch of curiosity, answering questions about how and why these mushrooms glow.

Bioluminescence, light emitted by living organisms, has been verified in only 71 of the roughly 100,000 described species in the Kingdom Fungi. These 71 species belong to four distantly related lineages occurring throughout the world, with greatest abundance in the tropics. Conspicuous temperate species include: the Jack-o-Lantern mushrooms of Europe and the North America (Omphalotus illudens, O. olearius), the ghost fungus of Australia and Asia (O. nidiformis), the moon night mushroom of Japan (O. japonicus), and various species of honey mushrooms whose mycelium causes "foxfire"—the phenomenon of glowing wood noticed by Aristotle.

Bioluminescence results when energy from a chemical reaction is released as light. Specifically this occurs when an enzyme, known as luciferase, catalyzes the oxidation of an organic molecule, known as luciferin.

In a recent study, published in Photochemical & Photobiological Sciences, 2012, researchers mixed luciferin and luciferase from various lineages of bioluminescent fungi. They found that all mixtures resulted in bioluminescence, which suggests "a single luminescent pathway" that arose early in these lineages.

Mycena luxaeterna
Mycena luxaeterna
Top: Mycena luxaeterna glowing in the dark. Bottom: Mycena luxaeterna. Photos by: Cassius V. Stevani, IQ-USP, Brazil.
While this study sheds light on the evolutionary pathway of these fungi, the exact compounds responsible for luminescence remain unknown. Once these compounds and their corresponding genes are known, scientists will be able to search for their presence in other fungi, further illuminating the evolutionary pathway of bioluminescence and perhaps answering important questions about their adaptive significance.

Fungi are one of the world's least studied life forms. There are presumably thousands of species remaining to be found, especially in the tropics. San Francisco State University professor and avid mycologist, Dr. Dennis Desjardin, has uncovered more than 200 new species of fungi and nearly a quarter of all glowing mushrooms. Dr. Desjardin was a contributing author to the 2012 Photochemical & Photobiological Sciences study and spoke with mongaby.com about his burgeoning field.

"Why do luminescent mushrooms, all of which emit light 24 hours per day, which must be an energy consumptive process, glow at all?" Desjardin asks. "There is no one answer to this question and we suspect that different species may glow for different reasons, especially dictated by which part of the mushroom or its mycelium glows."

Scientists do know that bioluminescence provides some antioxidant protection, and that the light attracts insects which may aid in spore dispersal. "We have evidence that in some species, insects are attracted to luminescent mushrooms more than they are to non-luminescent mushrooms of the same size and shape," explains Desjardin, " but whether glowing makes any significant difference to the mushroom species in spore dispersal is unknown."

If these questions leave you feeling inspired to head to the tropics to discover unknown fungi and unravel the secrets of glowing mushrooms, you may want to begin with an undergraduate degree in botany, or at least a few mycology courses. But for those who simply wish to witness bioluminescent fungi in action, Dr. Desjardin offers the following advice:

"There are a few species in temperate habitats that are luminescent, particularly Omphalotus species (jack-o-lantern mushrooms), but they are not very spectacular and it requires patience (sitting for a long time in the dark to let your eyes adjust). The tropics are the best place to see them. Brazil, Southeast Asia and Australia are particularly good places with a variety of luminescent mushroom species. Pick a new moon night during the rainy season, go out at night when it is completely dark, and roam in the forest looking for points of yellowish green light. Don't forget, however, that you cannot see a thing in the pitch dark, so you'll walk into trees, streams, etc, and that there are lots of creatures that are nocturnal, like poisonous snakes, jaguar, necrotic spiders, etc. that need to be avoided! It's lots of fun!"



Neonothopanus gardneri
Neonothopanus gardneri
Neonothopanus gardneri. Photos by: Cassius V. Stevani, IQ-USP, Brazil.



Mycena lucentipes.
Mycena lucentipes.
Mycena lucentipes. Photos by: Cassius V. Stevani, IQ-USP, Brazil.



CITATION: Oliveira, A. G., Desjardin, D.E., Perryc, B.A., and Stevani C.V. (2012) Evidence that a single bioluminescent system is shared by all known bioluminescent fungal lineages. Photochemical & Photobiological Sciences. 11, 848-852.













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CITATION:
By: Liz Kimbrough (June 13, 2013).

Why bioluminescent fungi glow in the dark.

http://news.mongabay.com/2013/0613-kimbrough-glowing-fungi.html