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The nutritional modes of genera in Hygrophoraceae (Basidiomycota: Agaricales), apart from the ectomycorrhizal Hygrophorus and lichen-forming taxa, are uncertain. New δ15N and δ13C values were obtained from 15 taxa under Hygrophoraceae collected in central Massachusetts and combined with isotopic datasets from five prior studies including a further 12 species using a data standardization method to allow cross-site comparison. Based on these data, we inferred the probable nutritional modes for species of Hygrophorus, Hygrocybe, Humidicutis, Cuphophyllus and Gliophorus. A phylogeny of Hygrophoraceae was constructed by maximum likelihood analysis of nuclear ribosomal 28S and 5.8S sequences and standardized δ15N and δ13C values were used for parsimony optimization on this phylogeny. Our results supported a mode of biotrophy in Hygrocybe, Humidicutis, Cuphophyllus and Gliophorus quantitatively unlike that in more than 450 other fungal taxa sampled in the present and prior studies. Parsimony optimization of stable isotope data suggests moderate conservation of nutritional strategies in Hygrophoraceae and a single switch to a predominantly ectomycorrhizal life strategy in the lineage leading to Hygrophorus. We conclude that Hygrophoraceae of previously unknown nutritional status are unlikely to be saprotrophs and are probably in symbiosis with bryophytes or other understory plants.
We thank Harvard Forest for permission to conduct fieldwork. Thanks to Jean Lodge for sharing unpublished data, to Gareth Griffith, Mark Brundrett and Neale Bougher for their guidance on Hygrophoraceae ecology, to P. Brandon Matheny for help with nomenclature, and to Alfredo Justo and Dimitris Floudas for technical assistance. Financial support was provided by National Science Foundation grants IOS-0843278 (DSH: PI) and IOS-0843366 (EAH: PI). This research was integrated with the course Molecular Ecology of Forest Fungi (BIOL 252) of Clark University. We thank the students of BIOL 252 and summer undergraduate assistants Maria Luisa Sandoval and Truc Duong for their participation in this project. This research was conducted in partial fulfillment of the requirements for the doctoral degree at Clark University.