RESUMEN
Fungi are the primary agents of terrestrial decomposition, yet our understanding of fungal biogeography lags far behind that of plants, animals and bacteria. Here, we use a trait-based approach to quantify the niches of 23 species of basidiomycete wood decay fungi from across North America, and explore the linkages among functional trait expression, climate and phylogeny. Our analysis reveals a fundamental trade-off between abiotic stress tolerance and competitive ability, whereby fungi with wide thermal and moisture niches exhibit lower displacement ability. The magnitude of this dominance-tolerance trade-off is partially related to the environmental conditions under which the fungi were collected, with thermal niche traits exhibiting the strongest climate relationships. Nevertheless, moisture and thermal dominance-tolerance patterns exhibited contrasting phylogenetic signals, suggesting that these trends are influenced by a combination of niche sorting along taxonomic lines in tandem with acclimation and adaptation at the level of the individual. Collectively, our work reveals key insight into the life history strategies of saprotrophic fungi, demonstrating consistent trait trade-offs across broad spatial scales.
Asunto(s)
Proteínas Fúngicas/genética , Hongos/fisiología , Proteínas Fúngicas/metabolismo , Hongos/clasificación , Hongos/genética , Hongos/aislamiento & purificación , Regulación Fúngica de la Expresión Génica , Filogenia , Estrés FisiológicoRESUMEN
The soil decomposer community is a primary driver of carbon cycling in forest ecosystems. Understanding the processes that structure this community is critical to our understanding of the global carbon cycle. In North American forests, soil fungal communities are regulated by grazing soil invertebrates, which are in turn controlled by the predatory red-backed salamander (Plethodon cinereus). The presence of these soil invertebrate taxa is known to exert direct top-down control via selective grazing on saprotrophic fungi, with direct consequences for biogeochemical cycling in soil. We investigated whether the removal of P. cinereus would relieve top-down control on decomposer fungal communities in a tri-trophic mesocosm study. Fungal communities were characterized using metabarcoding and high-throughput DNA sequencing. The ß-diversity of fungal communities differed between salamander presence and absence treatments with a strong effect on saprotrophic fungal communities. We concluded that P. cinereus, a mesopredator in the detritivore food chain, exerts a prominent control on the composition and functional diversity of fungal communities in soil through a multi-trophic top-down process. Given their capacity to govern the compositions of soil invertebrates, the activity of these amphibians may be important for regulating ecosystem function and nutrient cycling in temperate forest systems.