Edible fungi crops through mycoforestry, potential for carbon negative food production and mitigation of food and forestry conflicts.

Demand for agricultural land is a potent accelerating driver of global deforestation, presenting multiple interacting issues at different spatiotemporal scales. Here we show that inoculating the root system of tree planting stock with edible ectomycorrhizal fungi (EMF) can reduce the food-forestry land-use conflict, enabling appropriately managed forestry plantations to contribute to protein and calorie production and potentially increasing carbon sequestration. Although, when compared to other food groups, we show that EMF cultivation is inefficient in terms of land use with a needed area of ~668 m2 y kg-1 protein, the additional benefits are vast. Depending on the habitat type and tree age, greenhouse gas emissions may range from -858 to 526 kg CO2-eq kg-1 protein and the sequestration potential stands in stark contrast to nine other major food groups. Further, we calculate the missed food production opportunity of not incorporating EMF cultivation into current forestry activities, an approach that could enhance food security for millions of people. Given the additional biodiversity, conservational and rural socioeconomic potential, we call for action and development to realize the sustainable benefits of EMF cultivation.

A novel approach to combine food production with carbon sequestration, biodiversity and conservation goals.

Land use conflict is a major contributor to unsustainable deforestation rates, with agriculture being the primary driver. Demand for agricultural output is forecast to increase for years to come and the associated deforestation is a key driver in global declines of biodiversity. Moreover, deforestation is contributing to instability of agricultural production systems and reduces our ability to mitigate anthropogenically driven climate change. There is urgency in reducing this land use conflict and the cultivation of ectomycorrhizal fungi (EMF) may provide a partial solution. As an example, here we focus on Lactarius indigo, an edible and historically appreciated species with distribution in the Neotropics and Nearctic. Exploring the geographic spread and associated climate preferences, we describe how cultivation of this species can be combined with forest-based biodiversity and conservation goals. Detailing a full methodology, including mycelium production and how to create trees that may produce the fungus, we explore potential benefits. Combing data from the emerging field of EMF cultivation with nutritional studies, we show that a protein production of 7.31 kg per hectare should be possible, exceeding that of extensive pastoral beef production. In contrast to commercial agriculture, L. indigo cultivation may enhance biodiversity, contribute to conservational goals and create a net sink of greenhouse gases whilst at the same time producing a similar or higher level of protein per unit area than the most common agriculture use of deforested land. With such startling and clear benefits, we call for urgent action to further the development of such novel food production systems.