Growing edible mushrooms alongside trees can produce a valuable food source for millions of people while capturing carbon, a new study has found.
For the last two years, Paul Thomas, honorary professor at the University of Stirling’s Faculty of Natural Sciences, has been collating and analysing data from studies on the emerging field of mycoforestry.
His analysis found that the cultivation of edible ectomycorrhizal fungi (EMF) in forests may sequester up to 12.8 tonnes of carbon per hectare annually.
“Fungi that grow in symbiosis with living trees are used to create a food crop from new tree plantings, and we found that production of fungi using this system can lead to a very significant sequestration of greenhouse gas,” he said.
“This is a huge benefit which means that by producing this food we can actively help mitigate climate change.
“When we compared this with other major food groups, this is the only one that would result in such benefits – all other major food categories lead to a greenhouse gas emission during production.”
There is currently a significant global issue of land-use conflict between forestry and food production.
Scientists have said according to data for 2010 to 2020, net loss of forest area remains high at some 4.7 million hectares per year.
Demand for agricultural land is said to be the biggest driver of global deforestation and this is forecast to accelerate.
Professor Thomas said mushrooms growing on trees will not only reduce the need for deforestation to make way for crops, but also incentivise tree planting.
He said if the fungi-tree growing system was combined with current forestry activities, food production levels could be huge.
“For China alone, their forestry activity for the last 10 years could have put in place a food production system capable of enough calorific output to feed 4.6 million people annually,” he added.
With his results, he has called on scientists to join his research and to gather support from relevant agencies to act on his findings.
He added: “This food production system is highly scalable, realistic and a potentially powerful route to sequester greenhouse gas.
“It would help with biodiversity and conservation globally, triggering rural socio-economic development and providing an incentive for increased tree-planting rates with all the associated benefits that brings.”
The study, which Professor Thomas worked on in partnership with the dean of the Faculty of Natural Sciences, professor Alistair Jump, has been published in PNAS (The Proceedings of the National Academy of Sciences), a journal of The National Academy of Sciences (NAS).