Abstract
Soil bacterial communities are altered by anthropogenic drivers such as climate change-related warming and fertilization. However, we lack a predictive understanding of how bacterial communities respond to such global changes. Here, we tested whether phylogenetic information might be more predictive of the response of bacterial taxa to some forms of global change than others. We analysed the composition of soil bacterial communities from perturbation experiments that simulated warming, drought, elevated CO2 concentration and phosphorus (P) addition. Bacterial responses were phylogenetically conserved to all perturbations. The phylogenetic depth of these responses varied minimally among the types of perturbations and was similar when merging data across locations, implying that the context of particular locations did not affect the phylogenetic pattern of response. We further identified taxonomic groups that responded consistently to each type of perturbation. These patterns revealed that, at the level of family and above, most groups responded consistently to only one or two types of perturbations, suggesting that traits with different patterns of phylogenetic conservation underlie the responses to different perturbations. We conclude that a phylogenetic approach may be useful in predicting how soil bacterial communities respond to a variety of global changes.This article is part of the theme issue ‘Conceptual challenges in microbial community ecology’.
Highlights
Soil bacterial communities play critical roles in ecosystem functioning such as carbon transformation and stabilization, nutrient and biogeochemical cycling and plant host defence
We tested whether phylogenetic information might be more predictive of the response of bacterial taxa to some forms of global change than others
We conclude that a phylogenetic approach may be useful in predicting how soil bacterial communities respond to a variety of global changes
Summary
Soil bacterial communities play critical roles in ecosystem functioning such as carbon transformation and stabilization, nutrient and biogeochemical cycling and plant host defence. Here we re-analysed publicly available data on soil bacterial community composition from field experiments that simulated a variety of global changes, including warming, drought, elevated atmospheric CO2 concentration, P addition and increased soil pH This wider collection of types of experiments allowed us to test three new hypotheses. We hypothesized that, while a clade’s response to different perturbations would not generally be correlated [28,29], some clades might be consistently sensitive to environmental changes and several types of perturbations (figure 1d) This pattern might occur if a clade is adapted to responding positively to environment change––for instance, possessing traits that allow a bacterium to turn on reproduction quickly, persist under stressful conditions or use a wide range of substrates [20,30]. A clade might respond consistently negatively if members are highly specialized to their preferred environment, such that any change in their conditions results in a decline in abundance
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