Abstract
Fungi play a critical role in the degradation of organic matter. Because different combinations of fungi result in different rates of decomposition, determining how climate change will affect microbial composition and function is fundamental to predicting future environments. Fungal response to global change is patterned by genetic relatedness, resulting in communities with comparatively low phylogenetic diversity (PD). This may have important implications for the functional capacity of disturbed communities if lineages sensitive to disturbance also contain unique traits important for litter decomposition. Here we tested the relationship between PD and decomposition rates. Leaf litter fungi were isolated from the field and deployed in microcosms as mock communities along a gradient of initial PD, while species richness was held constant. Replicate communities were subject to nitrogen fertilization comparable to anthropogenic deposition levels. Carbon mineralization rates were measured over the course of 66 days. We found that nitrogen fertilization increased cumulative respiration by 24.8%, and that differences in respiration between fertilized and ambient communities diminished over the course of the experiment. Initial PD failed to predict respiration rates or their change in response to nitrogen fertilization, and there was no correlation between community similarity and respiration rates. Last, we detected no phylogenetic signal in the contributions of individual isolates to respiration rates. Our results suggest that the degree to which PD predicts ecosystem function will depend on environmental context.
Highlights
The ubiquity and abundance of terrestrial fungi is indicative of their pivotal role in providing ecosystem services
We found that all three measures of phylogenetic diversity (PD) were highly correlated (PD-nearest taxon index (NTI) R2 = 0.86; NTI-net relatedness index (NRI) R2 = 0.71; NRI-PD R2 = 0.96) and selection of one vs. another had no impact on the significance of any results
Nitrogen fertilization, and its interaction with time, appeared to drive respiration rates, with the earliest sampling dates of nitrogenfertilized microcosms showing the highest levels of respired carbon (Table 1)
Summary
The ubiquity and abundance of terrestrial fungi is indicative of their pivotal role in providing ecosystem services. Soils contain roughly twice the carbon of either the atmospheric or vegetation pools (Batjes, 1996), and nutrients in the litter layer are presumably the most labile and rapidly cycled. A few other studies have demonstrated a positive relationship between microbial species richness and community functioning by creating de novo assemblages of isolated microorganisms (Naeem et al, 2000; Bell et al, 2005). The basis of this relationship is the positive correlation between the number of species and the variety of different, perhaps complementary, traits that contribute to a functional process
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