Traditional knowledge and use of wild mushrooms by Mixtecs or Ñuu savi, the people of the rain, from Southeastern Mexico

The study communities are located in the Mixteca Alta region of Oaxaca, Mexico (Fig. 1). The San Juan Yuta community is located south of the municipality of San Juan Tamazola, Oaxaca, located at the geographical coordinates 17° 01′ 23″ N and 97° 10′ 05″ W at 1640 m a.s.l. The predominant climate is (A)C(w) (semi-warm sub-humid), with temperatures of 16–22 °C and summer rains. The Santa Catarina Estetla community is located southwest of the Santa María Peñoles municipality, Oaxaca, at 17° 01′ 35.63″ N and 97° 05′ 50.33″ W, at 2000 m a.s.l. The predominant climate is (A)C(w) (semi-warm sub-humid), with temperatures of 14–22 °C and summer rains. The community of San Andrés Yutatío is located in the southwestern portion of the municipality of Teozatlán de Segura y Luna, Oaxaca, at 17° 36′ 29.05″ N and 97° 53′ 37.91″ W, at 2000 m a.s.l. The predominant climate is C(w) (temperate sub-humid), with temperatures from 16 to 24 °C and summer rains. The community of San Miguel Tulancingo is located at the northwest of the city of Oaxaca at 17° 45′ 1.77″ N and 97° 26′ 29.40″ W, at an altitude between 2000 and 2700 m a.s.l. The predominant climate is C(w) (temperate sub-humid), with temperatures from 14 to 18 °C and summer rains. All of the climates categories of the studied communities were based on Köppen’s classification system [19].

The outstanding vegetation types in the communities of the study, following the classification of Rzedowski [20], are Pinus and Quercus forests, xerophytic scrubs (primarily sclerophyllous), palm groves and small areas of tropical deciduous forest. In the Pinus and Quercus forests, 12 species of pines and at least 15 oaks are recorded, with Pinus oaxacana and P. lawsonii among the most abundant trees. Secondary grasslands are located in small areas of these communities, composed by grasses, sedges and small annual herbs. The evergreen sclerophyllous shrubs are floristically very rich. The species that occur most frequently are Comarostaphylis polifolia and Forestiera rotundifolia. Secondary palm groves of Brahea dulcis and Brahea nitida occur in areas that are subject to periodic burning and logging of the oak forest. The tropical deciduous forest is dominated by species of Bursera and Pachycereus. The agriculture of Mixtec communities is of the subsistence and marginal types. Corn (Zea mays L.), beans (Phaseolus vulgaris L.), pumpkin (Cucurbita spp.) and chili peppers (Capsicun annuum L.) are the basis of their diet. The diet of the Mixtec peoples in these regions is also complemented by animal husbandry and collected food, primarily more than 90 edible plant species, including vegetables, fruits and roots [11, 12], wild mushrooms as well as, to a lesser extent, hunting and insect gathering.

During the rainy seasons from 2009 to 2014, field observations were conducted with the company of persons who were recognized by the community as having greater knowledge of wild forest elements, particularly fungi. These persons were selected through the “snowball” technique following a theoretical sampling methodology following Sandoval [21]. Different vegetation types were toured, and wild mushrooms of cultural importance were collected. Additionally photographs and fresh collected specimens were shown to participants to collect information. Under a method of participant observation, informal unstructured and semi-structured interviews were conducted with the informants [22]. Four annual visits were conducted in each community during the rainy season from February to September, during which 116 semi-structured and non-structured interviews were performed. In these interviews the following information was obtained : i) socio-demographic information including gender, age, language and community of residence of interviewees; ii) recognized fungal species; ii) local nomenclature and classification; iii) edible species; iv) species considered toxic; v) species with ludic use; vi) habitat of the fungi locally used; vi) mechanisms of transmission of knowledge; vi) traditional forms of mushroom preparation; vii) criteria of differentiation between edible and poisonous species. To test the hypothesis, official information published by Mexican Government Agencies presenting regional and local information of the studied communities related with the natural vegetation cover, soil erosion and economic marginalization were used [19, 23, 24]. This information was compared with the information gathered in the present work related to the richness of fungal species locally used in each of the four studied communities, which was indicative of the local traditional knowledge and use.

The collected specimens were photographed, their macro- and micromorphological features were described and the specimens dried for preservation [25]. Taxonomic identifications of the material were performed using the techniques proposed by Largent et al. [26] and Tulloss [27] along with the consultation of other studies [28‐35], among others. The nomenclature of scientific names of fungi was based on the Index Fungorum [36] and on the plants in the USDA database [37]. The labelled specimens were deposited in the Mycological Collection of the Department of Microbiology of the Postgraduate College, in Montecillo, State of Mexico.

In addition, a review of literature was conducted to collect traditional names for mushrooms in different linguistic variants of Mixtec in Oaxaca. For this activity, vocabularies and Mixtec-Spanish dictionaries published by the Summer Institute of Linguistics in Mexico were the primary materials reviewed [38‐48]. The etymological interpretation of the information presented in these dictionaries was always made in the context of the studies that cited the words related to mushrooms, other studies published in the area [as the Mixtec language has 81 language variations [4] and the meanings of words change between these variants] or based on ethnomycological research conducted in the region from 2009 to 2014, which was facilitated by the fact that the first author is a Mixtec speaker and native of the study area. The writing of the different terms in the Mixtec language was based on the nomenclature proposed by some Mixtec-Spanish dictionaries [41‐45].

The most widespread knowledge among the inhabitants of the communities is associated with the use of fungi as food; however, there is also knowledge associated with toxic fungi and with the ludic use of some species.

The timing of the onset of the reproductive phase of mushroom species is related to the rainy period. In general, it starts in February and ends in September. N. lepideus presents a phenological pattern of early fruiting; it can be collected in the months from February to April, whereas A. campestris can be found in May and early June with a prolonged early pattern.

In the mid-season months of highest precipitation, July and August, species such as A. sect. caesarea and Ustilago maydis develop, exhibiting a short phenology. In September, prolonged late-maturing species such as C. cibarius s. l. can be found.

Of the 116 mushroom species hitherto recorded in the study areas, 99 (93 %) species are Basidiomycetes and 7 (7 %) are Ascomycetes. Eigthy species (75 %) grow on soil/litter substrates, whereas the remaining 25 % develop on wood or other substrates, 80 species (75 %) are ectomycorrhizal, 22 species (21 %) are saprobionts and four are parasites (4 %) (Tables 3 and 4). H. lactifluorum and H. macrosporus parasitise R. brevipes, providing a leathery, hard consistency and orange or coffee colouring to the fungus, respectively. N. lepideus and S. commune are saprophytic species that, once dried, can be stored without losing their flavour, to be consumed during the months in which no mushroom species develop. P. radicata is a species that develops in the dead roots of the guachépil tree (Diphysa robinioides Benth.), whose development is encouraged on cropland because its flowers and young pods are also used as food.

With respect to the vegetation where fungi grow, most occur in places with pine-oak litter (Pinus oaxacana, P. lawsonii, P. michoacana, P. pseudostrobus, P. patula, P. montezumae, Quercus magnoliifolia, Q. castanea, Q. affinis, Q. urbanii, Q. rugosa, Q. laurina, Q. acutifolia, Juniperus flaccida and Arbutus xalapensis). Some species are found in microhabitats where pine (Pinus spp.) or oaks (Quercus spp.) predominate. The exceptions are H. lactifluorum, which prefers sites with a predominance of “yellow oak” (Quercus magnoliifolia Née) and pointleaf manzanita (Arctostaphylos pungens Kunth); species such as A. campestris, A. pampeanus and M. oreades grow in sites with secondary vegetation or pasture; and species such as H. petaloides, P. aff. eryngii, P. aff. dryinus and S. commune develop in the tropical deciduous forest where species of Copal (Bursera spp.), Tepehuaje tree (Lysiloma acapulcensis (Kunth) Benth) and round oak (Q. glaucoides M. Martens & Galeotti) can be found.

Despite the ongoing process of acculturation in the region under study, traditional knowledge is preserved and there is transmission of that knowledge to new generations. Knowledge is passed from parents to children in a dynamic and versatile way during the daily life activities in the field, beginning at an early age (seven or eight years or sooner) when they can go to the field. The main instruction is in the places where fungal species can be found and the identification of species that are edible, toxic and have ludic uses. At the time of collecting fungi, people cut the stipe, leaving the volva or stipe base. With this, fungal growth the next year is guaranteed. People know with certainty where each species develops and visit the same sites to collect useful wild mushrooms, constituting an initial notion of the growth of "something" under the earth that produces sporomes.

The main factors that influenced the richness, knowledge and use of edible mushrooms in the four studied communities were: i) the natural vegetation cover, for example in the communities of Santa Catarina Estetla and San Juan Yuta, which have 72 and 50 % of natural pine and oak forests, respectively, there was a greater richness and therefore, knowledge and use of wild edible fungi compared with the communities of San Miguel Tulancingo and San Andrés Yutatío in which there is no coniferous forest and the oak forest occupies only 40 % (Table 5); ii) soil degradation, San Miguel Tulancingo and San Andrés Yutatío, present high levels of soil erosion originated by high deforestation rates and therefore they showed smaller diversity and richness of wild edible fungi (Table 5); iii) inter- and intra-annual rainfall influenced the fruiting season, diversity and abundance of wild edible fungi, for example in 2013 increased rainfall was distributed during the months from May to November, which caused an extension of the phenological fruiting season and higher diversity and abundance of wild edible fungi in the studied communities. In contrast in 2011 the rainy season was restricted from June to September, which resulted in low production of wild edible fungi; iv) the degree of urbanization was inversely proportional to the knowledge and use of wild edible fungi as shown by the fact that the communities San Miguel Tulancingo and San Andrés Yutatío which are urban communities use a very low number of wild mushrooms;; and v) the average number of people in extreme poverty was directly proportional to the use and knowledge of wild edible fungi in the studied Mixtec communities (Table 5). It was found that not only a single environmental or cultural characteristic, but a combination of them including higher vegetation cover of natural pine and oak forests, lower soil erosion and higher economic marginalization showed a greater richness and knowledge of wild mushrooms in the studied communities.

There is no information on the commercialization of wild mushrooms in the studied communities. However, it is now common for people who live in the communities centre or other surrounding communities to ask farmers to obtain specific species for purchase; this occurs, for example, in the community of Santiago Huaxolotipac located in the Municipality of San Antonio Huitepec with the species H. repandum (xi´i tɨntaku, worm mushrooms). In this municipality, until recently, agricultural, livestock or harvest products such as wild mushrooms were used as currency in the regional tianguis or "open air market". Currently, during the rainy season, species such as A. sect. caesarea, C. cibarius s. l. and H. repandum are sold in the regional market of Zaachila, in the Central Valley and in the “Mercado de Abastos” [Food Market] of the city of Oaxaca. These species are collected and kept by farmers who bring their products to market, who originate in the Mixtec communities of San Miguel Peras and Santiago Tlazoyaltepec.

A preservation of tradicional knowledge among Mixtecs was recorded in the studied communities. Caballero [65] mentioned that in the community of San Antonio Huitepec in the Eastern Mixteca Alta region, from six or seven years of age, a child knows how to distinguish edible wild mushrooms without equivocation or fear. At the time of collecting fungi, people cut the stipe, leaving the volva or stipe base. With this, fungal growth the next year is guaranteed. People know with certainty where each species develops and visit the same sites to collect useful wild mushrooms, constituting an initial notion of the growth of "something" under the earth that produces sporomes.

In the community under study there are species with potential to be exploited in a sustainable way as a non-timber forest product for export to international markets, which could be an alternative for the conservation of mycological knowledge and resources. International trade in wild mushrooms is valued at billions of dollars annually. One reason for this high cost is that most species cannot be cultivated [89] and are of great interest for gourmet cooking in various European countries and North America [90]. Among the species with potential are Cantharellus cibarius s. l. and Boletus edulis s. l., which have estimated annual values according to the retail market of $1.67 billion and more than $250 million U.S. dollars, respectively. Additionally, Amanita sect. caesarea also has an international market. The main countries that demand these species are Canada, France, Italy, Spain, USA, China and Germany [91, 92].

Sustainable management of wild mushrooms among the Mixtecs would be enhanced by implementing the following strategies: i) transmission of technologies to local people in order to give an added value to the commercialization of mushrooms in the region, by methods such as dehydration, preparation of brines and vinaigrettes; ii) dissemination of existing knowledge of mushrooms growing in local communities with value in international markets, which can be an important source of economic resources locally; iii) promotion of use of species that are not consumed in the region and have edible potential; iv) development of mycotourism involving the local population, including activities such as mycological tours and mycogastronomy; v) biotechnological applications of mycological resources, including cultivation of saprophytic species of biocultural importance regionally, inoculation of edible ectomycorrhizal fungi in native tree species tending to reforestation of degraded areas and development of mycosilviculture including forest management practices tending to increase natural production of wild mushrooms, mainly ectomycorrhizal species; and vi) upgrading and strengthening of ecological, cultural and socioeconomic importance of mycological resources, through activities such as fairs, exhibitions and local culinary samples, with the participation of members of the Mixtec communities, local and national government and non-governmental organizations. Some of these strategies have been successfully developed and applied in several European and Asian regions, contributing to forest conservation and sustainable management of mycological resources and natural ecosystems [93‐95].