Gymnopodium floribundum Trees (Polygonaceae) Harbour a Diverse Ectomycorrhyzal Fungal Community in the Tropical Deciduous Forest of Southeastern Mexico

Abstract

最近开发的现场工作monodominant脱颖而出st of Gymnopodium floribundum (Polygonaceae) in the tropical deciduous forest established in southeastern Mexico (Chiapas State), led us to discover a number of above ground fruit bodies of putative ectomycorrhizal species of basidiomycetes families Boletaceae, Amanitaceae, Russulaceae, Cortinariaceae and Cantharellaceae, and also to know the edibility of basidiomes of Tremelloscypha gelatinosa and Lactarius chiapanenesis both hunted during the rainy season by local people for consumption. The presence of such fungal groups under Gymnopodium trees suggested the possibility that G. floribundum is an ectomycorrhyzal-forming tree. In the tropical forests of Mexico above- and below ground ectomycorrhizal fungal component has not been investigated and for tropical members of the Polygonaceae, the ectomycorrhizal associates of Coccoloba but not of Gymnopodium have been recorded. We develop research in order to document the ectomycorrhizal fungal community of G. floribundum in the tropical deciduous forest of southeastern Mexico

Keywords

Fungal ecology, Molecular ecology, Forestry, Soil science, Fungal morphology, Systematics.

Introduction

With the benefits provided by the molecular techniques in the study of ectomycorrhizal fungi (EcMF), our knowledge about the different lineages of species integrating the fungal communities in forest ecosystems has increased greatly. Beyond of records of above ground fruit bodies the EcMF communities are being more accurately revised, based on below ground distinctive root tips morphotypes. Numerous papers document the species diversity and community composition of EcMF in temperate forests, but also information on tropical habitats of the world is increasing [1-5]. Research in natural habitats that consider sporocaps/ ectomycorrizae to recognize specific native ectomycorrhizal plant/fungi symbionts or EcMF community composition supported by molecular information has been recently developed in Mexico [6-14]. In the last few years as part of our monitoring program to study the macrofungi inhabiting different forest ecosystems from Mexico, we have focused our research on recognizing ectomycorrhizal fungal species associated to putative ectomycorrhizal trees, especially on tree species or on forest ecosystems devoid of information about the specific mycobionts. Examining the above ground fruit bodies and the below ground ectomycorrhizae counterparts, morphologically documented and supported by molecular tools, we have recorded the association between Fagus grandifoliavar. mexicanatrees withLactaius badiopallescens, L. cinereusandL. fumosibrunneus, Carpinus carolinianawithL. indigo, Quercus xalapensiswithL. strigosipes,Quercus sp. withL. strigosipes; Turbinellus floccosuswithAbies religiosaandL. cuspidoaurantiacusandL. herrerae与Alnus acuminata[8,11-13].

Field work developed in a forest dominated byGymnopodium floribundum(Polygonaceae) in the tropical deciduous forest established in southeastern Mexico (Chiapas State) (Figure 1aand1b), led us to discover that the fruit bodies of theheterobasidiomycete Tremelloscypha gelatinosa(Figure 1c) locally named “nangañaña” are harvested during the rainy season by local people for consumption, whereasLactariuschiapanenesis known as “moni” (Figure 1d), is harvested for sale in popular markets of the region [8,15]. Tremelloscypha gelatinosa is a member of the Sebacinales group A and it is phylogenetically related to ectomycorrhizal species [16,17]. The presence ofLactarius chiapanenesisandTremelloscypha gelatinosaunderGymnopodiumtrees, suggested then, the possibility that G. floribundum is an ectomycorrhyzal-forming tree. Surprising indeed, during subsequent explorations in such tropical forest we found the occurrence of a number of fruit bodies of putative EcMF belonging tobasidiomycete families Boletaceae, Amanitaceae, Russulaceae, Cortinariaceae and Cantharellaceae(Figure 1eand1f) [18] . While lineages of these groups are recognized as important elements of the ectomycorrhizal fungal community in different tropical forest worldwide, in the tropical forests of Mexico above- and below ground EcMF component has not been investigated and for tropical members of the Polygonaceae, to our knowledge, the ectomycorrhizal associates ofCoccolobabut not ofGymnopodiumhave been recorded [18-29].

Figure 1:a. Gymnopodium forest panorama in the tropical deciduous forest under study. b.Gymnopodium floribundum. c. Tremelloscypha gelatinosa. d. Lactarius chiapanensis. e. Boletus sp. f. Inocybe sp.

Gymnopodium floribundumis monodominant over a number of hectares in the tropical deciduous forest under study (Figure 1a) and the presence of the component of EcMF now observed above ground is expected to be potentially richer in species at root tip level, in congruence with the assumption that in tropical habitats, the aggregations or dominance of ectomycorrhizal trees are favored by the interaction of associated EcMF and that monodominant forests may harbor a more diverse ectomycorrhizal community than mixed forest [30-32]. As this forest is continuously being fragmented, the ectomycorrhizal edible mushrooms could be an incentive for local communities to protect it. Local communities should learn about the value of the ecological role of the ectomycorrhizae for enhancing seedlings establishment and tree growth, and appreciate the relation of the presence of these later with the availability of fruit bodies production as an alternative to obtain a non-timber forest product, source of protein-rich food and of economic incomes.

We have in developing a long-term project to investigate the ectomycorrhizal fungal community ofGymnopodium floribundumin the tropical deciduous forest of southeastern Mexico with the following main goals: taxonomic studies to describe the ectomycorrhizal species (sporomes/ectomycorrhizas), recognize specific interactions analyzing root tips, document the species richness and the structure of the ECM fungal community.

References

1. Dickie IA and Moyersoen B. Towards a global view of ectomycorrhizal ecology. New Phytol. 2008;180: 263-265.
2. Peay KG, et al. Potential link between plant and fungal distributions in a dipterocarp rainforest: community and phylogenetic structure of tropical ectomycorrhizal fungi across a plant and soil ecotone. New Phytologist.2010;185:529–542.
3. Tedersoo L, et al. Ectomycorrhizal lifestyle in fungi: global diversity, distribution, and evolution of phylogenetic lineages. Mycorrhiza. 2010;20:217-263.
4. Smith ME, et al. Ectomycorrhizal fungal diversity and community structure on three co-occurring leguminous canopy tree species in a Neotropical rainforest. New Phytol.2011;192:699-712.
5. Séne S, et al. Ectomycorrhizal fungal communities of Coccolobauvifera (L.)L. mature trees and seedlings in the neotropical coastal forests of Guadeloupe (Lesser Antilles). Mycorrhiza. 2015.
6. Morris MH, et al. Multiple species of ectomycorrhizal fungi are frequently detected on individual oak root tips in a tropical cloud forest. Mycorrhiza. 2008;18:375-383.
7. Valdés M, et al. The ectomycorrhizal community in a Pinusoaxacana forest under different silvicultural treatment. J. Trop. For. Sci. 2009;21:88-97.
8. Montoya L and Haug I, Bandala VM. Two Lactarius species associated with a relict Fagusgrandifolia var. mexicana population in a Mexican montane cloud forest. Mycologia. 2010;102:153-162.
9. Montoya L,et al. New and interesting species of Lactarius from Mexico including scanning electron microscope observations.Mycotaxon. 1996;57:411-424.
10. Kennedy PG, et al. Ectomycorrhizal fungi in Mexican Alnus forests support the host co-migration hypothesis and continental-scale patterns in phylogeography. Mycorrhiza. 2011;21:559-568.
11. Garay-Serrano E, et al. Morphological and molecular identification of the ectomycorrhizal association of Lactariusfumosibrunneus and Fagusgrandifolia var. mexicana trees in eastern Mexico. Mycorrhiza. 2012;22:583-588.
12. 12.Lamus MV, et al. Ectomycorrhizal association of three Lactarius species with Carpinus and Quercus trees in a Mexican montane cloud forest. Mycologia. 2012;104:1261-1266.
13. Lamus MV, et al. Ectomycorrhizal association of three Lactarius species with Carpinus and Quercus trees in a Mexican montane cloud forest. Mycologia. 2012;104:1261-1266.
14. Lamus MV, et al. Mycorrhizal synthesis of the edible mushroom Turbinellusfloccosus With Abiesreligiosa from central Mexico. Mycoscience. 2015.
15. GaribayOrijel R, et al. Caracterizaciónmorfológica y genética de lasectomicorrizasformadas entre Pinusmontezumae y los hongospresentes en los bancos de esporas en la FajaVolcánicaTransmexicana. Revista Mexicana de Biodiversidad. 2013;84:153–169.
16. Bandala VM, et al. “Nangañaña” (Tremelloscyphagelatinosa, Sebacinaceae), hongosilvestre comestible delbosque tropical deciduo en la depresión central de Chiapas, México. Acta Bot. Mex. 2014;106:149-159.
17. 魏ßM和Oberwinkler Phylogenetic relationships in Auriculariales and related groups -hypotheses derived from nuclear ribosomal DNA sequences. Mycol. Res. 2001;105:403-415.
18. Bandala VM and Montoya L. Macrohongosectomicorrizógenos en bosque tropical de Gymnopodium (Polygonaceae) en el sur de México.Abstracts, VIII CongresoLatinoamericano de Micología, Medellín, Colombia. 2014.
19. Weiß M, et al.Sebacinales:a hitherto overlooked cosm of heterobasidiomycetes with a broad mycorrhizal potential. Mycol. Res.2004;108:1003-1010.
20. Henkel TW, et al. Ectomycorrhizal fungi and their leguminous hosts in the Pakaraima Mountains of Guyana. Mycol. Res. 2002;106:515-531.
21. Lee LS, et al. Ectomycorrhizas and putative ectomycorrhizal fungi of ShorealeprosulaMiq (Dipterocarpaceae). Mycorrhiza. 1997;7:63–81.
22. Smith ME, et al. The ectomycorrhizal fungal community in a neotropical forest dominated by the endemic dipterocarpPakaraimaeadipterocarpacea. PLoS One. 2013;8:e55160.
23. Bandou E, et al. The ectomycorrhizal fungus Scleroderma bermudense alleviates salt stress in seagrape (Coccolobauvifera L.)seedlings. Mycorrhiza. 2006;16:559-565.
24. Becerra AG and Zak MR. The ectomycorrhizal symbiosis in South America: morphology, colonization, and diversity. Pp. 19-41. In Rai M. and Varma A. (eds.), Diversity and biotechnology of ectomycorrhizae.Soil Biology 25. Springer-Verlag Berlin. 2011.
25. Brundrett MC. Mycorrhizal associations and other means of nutrition of vascular plants: understanding the global diversity of host plants by resolving conflicting information and developing reliable means of diagnosis. Plant Soil. 2009;320:37-77.
26. Buyck B and Ovrebo CL. New and interesting Russula species from Panama.Mycologia. 2002;94:888-901.
27. Kennedy PG, et al. Scaling up: examining the macroecology of ectomycorrhizal fungi. Mol Ecol. 2012;21:4151-4154.
28. Miller OK, et al. New and Interesting Ectomycorrhizal Fungi from Puerto Rico, Mona, and Guana Islands.Mycologia. 2000;92:558-570.
29. Pegler DN. Agaric flora of the Lesser Antilles. Kew Bull Add Ser.1983;IX:1-668.
30. Wang B and Qiu YL. Phylogenetic distribution and evolution of mycorrhizas in land plants.Mycorrhiza. 2006;16:299-363.
31. Torti SD, et al. Causes and consequences of monodominance in tropical lowland forests. Am Nat.2001;157:141-153.
32. McGuire KL. Common ectomycorrhizal networks may maintain monodominance in a tropical rain forest. Ecology.2007; 88:567-574.